CN111800248A

CN111800248A - Communication method and device based on virtual carrier data mode

Info

Publication number: CN111800248A
Application number: CN202010469955.7A
Authority: CN
Inventors: 韦臣龙
Original assignee: Individual
Current assignee: Individual
Priority date: 2020-05-28
Filing date: 2020-05-28
Publication date: 2020-10-20
Anticipated expiration: 2040-05-28
Also published as: CN111800248B

Abstract

The embodiment of the invention discloses a communication method and a device based on a virtual carrier data mode, wherein the communication method comprises the following steps: extracting a data segment to be sent; modulating the data segment to be transmitted in a transmission signal with a starting point and an end point by using a frequency oscillation module arranged in a transmitting end as oscillation frequency data; and accumulating the control frequency number corresponding to the data segment to be sent, which is generated by the frequency oscillation module, by using a preset frequency counter module, obtaining a target transmission signal to be sent when the frequency counter module accumulates the control frequency number to be sent, and triggering a controller to control an execution sending device to stop sending the transmission signal. The communication method based on the virtual carrier data mode can realize the transmission of communication data by adopting the virtual carrier mode, has simple and convenient installation and lower cost, and improves the transmission efficiency of the communication data.

Description

Communication method and device based on virtual carrier data mode

Technical Field

The embodiment of the invention relates to the field of data communication, in particular to a communication method and a communication device realized based on a virtual carrier data mode, and further relates to a sending end communication system realized based on the virtual carrier data mode, a receiving end communication system realized based on the virtual carrier data mode and a computer readable storage medium.

Background

In recent years, with the rapid development of network technologies, wireless communication is becoming mature and its application range is gradually expanding. However, with the rapid development of economic society, the requirements of various industries on wireless communication technology are higher and higher. Therefore, how to further improve the efficiency of wireless communication based on the existing communication technology and communication facilities has become an urgent problem to be solved in the field.

Wireless communication technology is generally a form of communication that relies on electromagnetic waves for information transfer and exchange. Currently, fourth and fifth generation mobile communication technologies, i.e. 4G network and 5G network, are introduced. Wireless communication may utilize electromagnetic waves for modulated carrier communication. With the development of wireless communication technology, the frequency of the used electric wave is higher, and the higher the frequency is, the higher the transmission rate is. But the electromagnetic wave has the following characteristics: the higher the frequency, the shorter the wavelength, the closer to straight line propagation (worse diffraction capability), and the higher the frequency, the greater the attenuation in the propagation medium. If the high frequency band is used, the transmission distance is greatly shortened, the coverage capability is greatly weakened, and more base station terminal equipment must be arranged, which results in increased cost.

In the era of interconnection of everything, the demand for network data transmission is increasing, and in order to meet the huge demand for data transmission and reduce the use cost, a novel communication method and device for modulating and demodulating signals are urgently needed in the field.

Disclosure of Invention

Therefore, embodiments of the present invention provide a communication method implemented based on a virtual carrier data manner, so as to solve the problem in the prior art that communication efficiency is low due to being easily affected by bandwidth changes.

In order to achieve the above object, the embodiments of the present invention provide the following technical solutions:

in a first aspect, an embodiment of the present invention provides a communication method implemented based on a virtual carrier data manner, where the method includes: extracting a data segment to be sent; modulating the size of the data segment to be transmitted in a transmission signal with a starting point and an ending point as oscillation frequency data by using a frequency oscillation module arranged in a transmitting end; wherein the transmission signal comprises a transmission carrier of a continuous signal or a carrier signal; and accumulating the control frequency number corresponding to the data segment to be sent, which is generated by the frequency oscillation module, by using a preset frequency counter module, obtaining a target transmission signal to be sent when the frequency counter module accumulates the control frequency number to be sent, and triggering a controller to control an execution sending device to stop sending the transmission signal.

Further, the communication method implemented based on the virtual carrier data method further includes: and respectively setting carrier characteristics or signals for one or more groups of combination identifications to start transmission and end transmission at the starting point and the end point during modulation.

Further, the transmission carrier includes a conductor electric signal and a radio wave signal.

In a second aspect, an embodiment of the present invention further provides a communication apparatus implemented based on a virtual carrier data manner, where the communication apparatus includes: a data segment extraction unit, configured to extract a data segment to be sent; the modulation unit is used for modulating the size of the data segment to be transmitted in a transmission signal with a starting point and an end point as oscillation frequency data by utilizing a frequency oscillation module arranged in a transmitting end; wherein the transmission signal comprises a transmission carrier of a continuous signal or a carrier signal; and the frequency counting unit is used for accumulating the control frequency number corresponding to the data segment to be sent, which is generated by the frequency oscillation module, by using a preset frequency counter module, obtaining a target transmission signal to be sent when the frequency counter module accumulates the control frequency number to be sent, and triggering a controller to control and execute the sending device to stop sending the transmission signal.

Further, the communication apparatus implemented based on the virtual carrier data scheme further includes: and the mark setting unit is used for respectively setting carrier wave characteristics or signals for one or more groups of combined marks to start and end transmission at the starting point and the end point during modulation.

In a third aspect, an embodiment of the present invention further provides a communication method implemented based on a virtual carrier data manner, where the communication method includes: when a receiving end receives a target transmission signal sent by the communication method realized based on the virtual carrier data mode, accumulating the control frequency number of the frequency oscillation module by using a frequency counting module arranged in the receiving end; the target transmission signal is a continuous or carrier signal with a starting point and an ending point, and carrier characteristics or signals for starting transmission and ending transmission of one or more groups of combined identifications are respectively set at the starting point and the ending point; when the frequency counting module accumulates to the end point of the target transmission signal, ending accumulating the control frequency number; and restoring the control frequency number corresponding to the target transmission signal from the starting point to the end point by using a frequency oscillation module arranged in the receiving end to obtain a restored transmission signal, and taking the restored transmission signal as an actual transmission signal of the transmitting end.

Further, the communication method implemented based on the virtual carrier data method further includes: acquiring the actual control frequency number corresponding to the actual transmission signal accumulated by the frequency counting module; and obtaining a calibrated actual transmission signal based on a calibration coefficient calculated by a preset protocol calibration signal standard value and an actual control frequency number of the received calibration signal, and transmitting the calibrated actual transmission signal to a preset using module.

In a fourth aspect, an embodiment of the present invention further provides a communication apparatus implemented based on a virtual carrier data manner, where the communication apparatus includes: a frequency counting unit, configured to accumulate the control frequency number of the frequency oscillation module by using a frequency counting module built in a receiving end when the receiving end receives a target transmission signal transmitted by the communication method implemented based on the virtual carrier data manner according to claim 1; the target transmission signal is a continuous signal or a carrier signal with a starting point and an ending point, and carrier characteristics or signals for starting transmission and ending transmission of one or more groups of combined identifications are respectively set at the starting point and the ending point; the end frequency counting unit is used for ending the accumulation of the control frequency number when the frequency counting module accumulates to the end point of the target transmission signal; and the restoring unit is used for restoring the control frequency number corresponding to the received target transmission signal from the starting point to the ending point by using a frequency oscillation module arranged in the receiving end to obtain a restored transmission signal, and taking the restored transmission signal as an actual transmission signal of the transmitting end. And the calibration unit is used for obtaining the actual control frequency number corresponding to the actual transmission signal accumulated by the frequency counting module, calculating a calibration coefficient calculated based on a preset protocol calibration signal standard value and the actual control frequency number of the received calibration signal, obtaining a calibrated actual transmission signal, and transmitting the calibrated actual transmission signal to a preset using module.

Further, the communication apparatus implemented based on the virtual carrier data scheme further includes: an actual control frequency number obtaining unit, configured to obtain an actual control frequency number corresponding to the actual transmission signal, which is accumulated by the frequency counting module; and the calibration unit is used for calculating according to a preset algorithm based on a pre-calculated calibration coefficient and the actual control frequency number, obtaining a calibrated actual transmission signal and transmitting the calibrated actual transmission signal to a preset using module.

In a fifth aspect, an embodiment of the present invention further provides a sending-end communication system implemented based on a virtual carrier data manner, where the sending-end communication system includes: the device comprises a built-in power supply module, a frequency oscillator module, a frequency counter module, a controller and an execution transmitting device;

the built-in power supply module is used for providing electric energy for the frequency oscillator module, the frequency counting module, the controller and the execution transmitting device;

the frequency oscillator module is used for modulating a data segment to be transmitted in a transmission signal with a starting point and an end point as oscillation frequency data; the transmission signal is a carrier signal with a starting point and an ending point, and carrier characteristics or signals used for starting and ending transmission of a group of identifiers are respectively set at the starting point and the ending point;

the frequency counting module is used for accumulating the starting point and the ending point corresponding to the control frequency number of the data segment to be sent, which is generated by the frequency oscillation module;

the controller is used for controlling the transmission signal to start or stop transmitting according to the time of the starting point and the ending point acquired by the frequency counting module;

the execution sending device is used for starting sending the transmission signal or stopping sending the transmission signal according to the control signal which controls the transmission signal to start sending and end sending.

In a sixth aspect, an embodiment of the present invention further provides a receiving end communication system implemented based on a virtual carrier data manner, where the receiving end communication system includes: the device comprises a receiving device, a built-in power supply module, a frequency oscillator module, a frequency metering module and a calibration module;

the built-in power supply module is used for providing electric energy for the receiving device, the frequency oscillator module, the frequency counting module and the calibration module;

the receiving device is used for receiving a target transmission signal sent by a sending end; the target transmission signal is a continuous signal or a carrier signal with a starting point and an ending point, and a group of carrier characteristics or signals for marking the start of transmission and the end of transmission are respectively arranged at the starting point and the ending point;

the frequency counting module is used for starting to accumulate control frequency numbers corresponding to the transmission signals after the receiving device receives the transmission signals sent by the sending end, and ending to accumulate the control frequency numbers when the control frequency numbers are accumulated to the end point of the target transmission signals;

the frequency oscillation module is used for restoring the control frequency number accumulated by the frequency counting module to obtain an actual transmission signal;

the calibration module is configured to obtain an actual control frequency number corresponding to the actual transmission signal accumulated by the frequency counting module, calculate a calibration coefficient based on a preset protocol calibration signal standard value and the actual control frequency number of the received calibration signal, obtain a calibrated actual transmission signal, and transmit the calibrated actual transmission signal to a preset using module.

In a seventh aspect, an embodiment of the present invention further provides an electronic device, including: a processor and a memory; the memory is configured to store a program of a communication method implemented based on a virtual carrier data method, and after the electronic device is powered on and the processor runs the program of the communication method implemented based on the virtual carrier data method, the electronic device executes any one of the above-mentioned communication methods implemented based on the virtual carrier data method.

In an eighth aspect, an embodiment of the present invention further provides a computer-readable storage medium, where the computer-readable storage medium contains one or more program instructions, and the one or more program instructions are used for a server to execute any one of the above communication methods implemented based on a virtual carrier data manner.

In a ninth aspect, an embodiment of the present invention further provides a storage method implemented based on a virtual carrier data manner, where the storage method includes: acquiring a data packet to be stored;

controlling a data packet to record continuous signal marks in a storage unit according to a preset sequence by using a preset controller with a counter function, and recording the number of bits by taking the bits in the storage unit as a unit; when one bit is written in, controlling the counter to count once correspondingly, starting to write in the subsequent data packet after the number of write-in times of the corresponding size of the data packet is reached, and sequentially controlling the data of the subsequent data packet to be written in the storage unit; the number of the bits is the number of each combination mode formed by arranging and combining a plurality of bits contained in the data of the data packet; and each stored data packet is stored according to a preset system, and the preset system is stored by taking the size of the data packet as a system storage unit.

In a tenth aspect, an embodiment of the present invention further provides a storage apparatus implemented based on a virtual carrier data manner, where the storage apparatus includes: the data acquisition unit is used for acquiring a data packet to be stored;

the data storage unit is used for controlling the data packets to record continuous signal marks in the storage unit according to a preset sequence by utilizing a preset controller with a counter function, and the number of the bits is recorded by taking the bits in the storage unit as a unit; when one bit is written in, the counter is controlled to count once correspondingly, when the number of writing times of the size of the data packet is reached, the subsequent data packet is written in, and the data of the subsequent data packet is controlled to be written in the storage unit in sequence; the number of the bits is the number of data of the data packet or each combination mode formed by arranging and combining a plurality of bits; and each stored data packet is stored according to a preset system, and the preset system is stored by taking the size of the data packet as a system storage unit.

In an eleventh aspect, an embodiment of the present invention further provides a computer-readable storage medium, where the computer storage medium contains one or more program instructions, and the one or more program instructions are used for a server to execute the storage method implemented based on the virtual carrier data manner according to claim 11; or the one or more program instructions are used for the server to execute the file that the data packet counts in any binary system and a plurality of virtual bits in an arrangement combination mode, and the file is stored and transmitted according to a compatible 0/1 file mode; the arrangement and combination mode of the plurality of virtual bits is the number of the virtual bits participating in data arrangement and combination set according to requirements; the server executes compression and decompression operations on various files in a software programming mode; the storage system is modified and upgraded in a hardware development mode; wherein, the server refers to a computer system; the modification and upgrade of the storage system comprises the following steps: adding preset counter module, system conversion module, bit permutation combination decoding and encoder into hard disk for storage system

In a twelfth aspect, an embodiment of the present invention further provides a data calculation processing method implemented based on a virtual carrier data manner, where the method includes: receiving a data packet sent by a superior controller based on a preset instruction receiving module; wherein the data packet includes at least one of tuning data, temporary storage, accumulation data, subtraction data, and movement data; converting the data packet into a data packet with the same system number based on a preset instruction controller containing an instruction set and a register; calculating the data packet by using a preset counter module in a superposition or superposition-subtraction calculation mode; wherein the counter module comprises an accumulation control counter module and/or an accumulation and reduction counter module.

In a thirteenth aspect, an embodiment of the present invention further provides a data calculation processing apparatus implemented based on a virtual carrier data manner, including: the data receiving unit is used for receiving a data packet sent by the superior controller based on a preset instruction receiving module; wherein the data packet includes at least one of tuning data, temporary storage, accumulation data, subtraction data, and movement data; the data conversion unit is used for converting the data packet into a data packet with the same system number based on a preset instruction controller containing an instruction set and a register; the data processing unit is used for utilizing a preset counter module to calculate and process the data packet in a superposition or superposition-subtraction calculation mode; wherein the counter module comprises an accumulation control counter module and/or an accumulation and reduction counter module.

The communication method based on the virtual carrier data mode can realize the transmission of communication data by adopting the virtual carrier mode, has simple and convenient installation and lower cost, improves the processing efficiency of the communication data, and further improves the use experience of users.

The storage method based on the virtual carrier data mode can realize the data storage by adopting the virtual carrier mode, has lower cost and improves the processing efficiency of communication data.

The computing method based on the virtual carrier data mode can realize the data computing and processing by adopting the virtual carrier mode, has lower cost and improves the processing efficiency of the communication data.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below. It should be apparent that the drawings in the following description are merely exemplary, and that other embodiments can be derived from the drawings provided by those of ordinary skill in the art without inventive effort.

Fig. 1 is a flowchart of a communication method implemented at a sending end based on a virtual carrier data manner according to an embodiment of the present invention;

fig. 2 is a schematic diagram of a communication apparatus implemented at a sending end based on a virtual carrier data manner according to an embodiment of the present invention;

fig. 3 is a flowchart of a communication method implemented at a receiving end based on a virtual carrier data manner according to an embodiment of the present invention;

fig. 4 is a schematic diagram of a communication apparatus implemented at a receiving end based on a virtual carrier data manner according to an embodiment of the present invention;

fig. 5 is a schematic diagram of a transmitting-end communication system implemented based on a virtual carrier data manner according to an embodiment of the present invention;

fig. 6 is a schematic diagram of a transmitting-end communication system implemented based on a virtual carrier data manner according to an embodiment of the present invention;

fig. 7 is a schematic diagram of a transmitting-end communication system implemented based on a virtual carrier data manner according to an embodiment of the present invention;

fig. 8 is a schematic diagram of a transmitting-end communication system implemented based on a virtual carrier data manner according to an embodiment of the present invention.

Detailed Description

The present invention is described in terms of particular embodiments, other advantages and features of the invention will become apparent to those skilled in the art from the following disclosure, and it is to be understood that the described embodiments are merely exemplary of the invention and that it is not intended to limit the invention to the particular embodiments disclosed. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

The following describes an embodiment of a communication method implemented based on a virtual carrier data method according to the present invention in detail. As shown in fig. 1, which is a flowchart of a communication method implemented at a receiving end based on a virtual carrier data manner according to an embodiment of the present invention, a specific implementation process includes the following steps:

step S101: and extracting a data segment to be transmitted.

Step S102: and modulating the data segment to be transmitted in a transmission signal with a starting point and an ending point by using a frequency oscillation module arranged in a transmitting end as oscillation frequency data.

After the data segment to be transmitted is extracted in step S101, in step S102, the data segment to be transmitted can be modulated as oscillation frequency data in a transmission signal having a start point and an end point by using a frequency oscillation module built in the transmitting end. Wherein, carrier characteristics or signals for a group of identifiers (including multiple groups of composite combinations) to start transmission and end transmission can be set at the starting point and the ending point respectively during modulation.

The transmission signal comprises transmission carriers such as continuous signals or carrier signals; the transmission carrier includes a wire electric signal and a radio wave signal, and specifically includes a 2G communication signal, a 3G communication signal, a 4G communication signal, a microwave communication signal, a satellite communication signal, a light wave communication signal, a radio frequency modulation signal, a WiFi signal, a sound wave communication signal, and the like, and is not limited in particular herein.

Step S103: and accumulating the control frequency number corresponding to the data segment to be sent, which is generated by the frequency oscillation module, by using a preset frequency counter module, obtaining a target transmission signal to be sent when the frequency counter module accumulates the control frequency number to be sent, and triggering a controller to control an execution sending device to stop sending the transmission signal.

After the modulation by the frequency oscillation module in step S102, in this step, a preset frequency counter module may be used to accumulate the control frequency number corresponding to the data segment to be transmitted, which is generated by the frequency oscillation module, so as to obtain a target transmission signal to be transmitted.

Fig. 7 is a schematic diagram of a transmitting-end communication system implemented based on a virtual carrier data manner according to an embodiment of the present invention.

In the embodiment of the present invention, the transmitting end may have a power module, a frequency oscillator module, a frequency counter module, a controller, an execution transmitting apparatus, and the like built therein. The controller can realize frequency counting of any initial accumulated control frequency quantity and sending and ending of control signals; the execution transmitting device may control the start of transmission and the end of transmission of the transmission signal according to a control signal transmitted by the controller.

Specifically, the working process of the sending end includes: a. firstly, extracting a data segment to be sent; b. it should be noted that, when the existing carrier communication is compatible, a carrier characteristic or signal representing the starting point transmission can be set at the starting point, and the carrier characteristic or signal has a group of representativeness in the carrier communication and can be identified by a receiving end; c. and when the frequency counter module accumulates the data segment needing to be transmitted, the trigger controller controls the execution transmitting device to stop transmitting the transmission signal.

When a plurality of data segments are transmitted simultaneously, the control frequency number corresponding to the second data segment to be transmitted can be started to be accumulated after a transmission point corresponding to the second data segment to be transmitted and indicating that data transmission is started is detected, and the accumulation of the control frequency number corresponding to the second data segment to be transmitted is triggered to be stopped after an end point corresponding to the second data segment to be transmitted and indicating that data transmission is stopped is detected. It should be noted that, when compatible with the existing carrier communication, in order to transmit a characteristic or signal representing the end point of the carrier, the characteristic value or signal needs to have a group of representatives in the carrier, which can be received by the receiving end. The steps a-b-c are repeated to realize the transmission of a plurality of data segments. The first data segment and the last data segment must be transmitted such that the receiving end can receive continuous signals or carrier signals from the starting point and the ending point of the signal, but cannot be continuous signal-free segments.

In the embodiment of the invention, as the virtual carrier frequency number signal is adopted, data can be loaded in the process of starting point and ending point of any transmission signal, any continuous signal capable of recording the start and the end of the transmission signal or carrier signal with the starting point and the ending point of the carrier can be used as the transmission carrier, and the transmission medium can be flexibly selected; such as currently used 2G communication signals, 3G communication signals, 4G communication signals, microwave communication signals, satellite communication signals, light wave communication signals, sound wave communication signals, etc., even the transmission and propagation of virtual frequencies can be completed by modulating the start and end point characteristic value signals in the network of the existing equipment, such as 10^15 Hz or even higher. In addition, the carrier can be combined with the existing network for use, and the description is omitted.

The structure setting of sending end is simple in this embodiment, and realizes easily, consequently can reform transform on the basis of existing equipment, also can reduce precision transmission and receipt and reach the high reliable reducibility of data in the transmission of complex environment medium when service environment such as weather changes badly in super high accuracy grade equipment.

In the practical implementation process, when larger data is directly transmitted, the transmission efficiency of the technical scheme disclosed by the invention is possibly lower; such as: binary data 1001110001000 of 5000 is transmitted, data loading only occupies 13 bits in carrier communication, and the transmission can be finished by using the method of the patent and needing the frequency oscillation module to oscillate 5000 times in frequency; although the signal does not need a carrier wave, a very high oscillation frequency is required at the transmitting end and the receiving end, and the communication efficiency is still low. In order to solve the defect, the decimal plus digit identification code can be spread in the form of thousand digits, hundred digits, ten digits and one digit, so that the problem of certain efficiency can be solved, and the decimal plus digit identification code can be converted into other systems which are easy to convert, identify and read by a computer for transmission, such as hexadecimal and the like; the process can be realized only by arranging corresponding converter modules at the transmitting end and the receiving end, and direct superposition transmission of pre-designed rules such as 1 frequency number representing 0 and 2 frequency number representing 1 can also be adopted in binary transmission, so that the transmission efficiency based on virtual carrier data communication is greatly improved.

The technical scheme disclosed by the invention can realize data modulation and demodulation communication transmission in a virtual carrier data (virtual carrier frequency number) mode. In the specific implementation process, the sending end and the receiving end need to have frequency oscillators with the same frequency and reach the precision level of corresponding requirements.

It should be noted that, aiming at the defects and shortcomings existing in the data communication transmission process based on the binary means in the prior art, the technical scheme disclosed by the invention redefines the data communication transmission in a new principle mode and can be compatible with the existing binary data; the invention can also be used comprehensively on the basis of the prior art, for example, the composite technology is designed by using the technology of the invention and the original modulation and demodulation mode. Specifically, the communication method based on virtual carrier data (virtual carrier frequency number) modulation and demodulation can be transmitted in various media (wires, optical fibers, wireless and the like), and can be applied to wireless 2G networks, 3G networks, 4G networks, 5G networks, satellite communication and microwave communication. Therefore, it can be used as a supplement to the existing wireless communication means, is compatible with the implementation form of the current wireless communication technology, and can also be used for independently transmitting communication data, which is not limited in detail herein.

In one specific comparative example, for example: the decimal number 302 needs to be transmitted after the binary 100101110 digital is used for modulating carrier wave, but in the method of the invention, only the ' 302 ' nanosecond (the ' 100101110 ' nanosecond ' binary system is continued below) needs to be directly continued in the form of any signal, such as 2G communication signal, 3G communication signal, 4G communication signal and other carrier wave signals transmitted by media, because a frequency oscillation counting control system with nanosecond precision (comprising a frequency oscillation module with nanosecond precision and a frequency counter module with nanosecond precision) is adopted, the decimal number can be obtained according to nanosecond-10 ^9 seconds, and 10^9bit data (with 10^15bit data in the same reason) can be transmitted in one channel within 1 second. The 2G communication signal, the 3G communication signal, and the 4G communication signal need to be modulated in advance into signals that can be disconnected at any time without affecting carrier data.

In the embodiment of the present invention, the data storage unit is generally represented by bit, B, KB, MB, GB, TB, PB, EB, ZB, YB, BB, NB, and DB … …. Wherein bit is a digit of a binary number, which can be 0 or 1, and is the minimum unit of data in a computer.

The communication method realized at the sending end based on the virtual carrier data mode can realize the transmission of communication data by adopting the virtual carrier mode, is simple and convenient to install, not only expands the data communication mode, but also overcomes the defects of carrier wireless communication, reduces the cost of wireless communication and simultaneously improves the transmission efficiency of communication data.

Corresponding to the communication method realized based on the virtual carrier data mode, the invention also provides a communication device realized based on the virtual carrier data mode. Since the embodiment of the apparatus is similar to the above method embodiment, the description is relatively simple, and please refer to the description of the above method embodiment, and the following description is only exemplary of an embodiment of a communication apparatus implemented based on a virtual carrier data method. Fig. 2 is a schematic diagram of a communication apparatus implemented at a receiving end based on a virtual carrier data manner according to an embodiment of the present invention.

The communication device realized at the sending end based on the virtual carrier data mode comprises the following parts:

a data segment extracting unit 201, configured to extract a data segment to be sent.

A modulation unit 202, configured to modulate the data segment to be transmitted as oscillation frequency data in a transmission signal having a start point and an end point by using a frequency oscillation module built in a transmitting end; wherein, the transmission signal comprises a transmission carrier such as a continuous signal or a carrier signal.

The frequency counting unit 203 is configured to accumulate the control frequency number corresponding to the to-be-transmitted data segment, which is generated by the frequency oscillation module, by using a preset frequency counter module, obtain a to-be-transmitted target transmission signal when the frequency counter module accumulates the control frequency number to be transmitted, and trigger the controller to control the execution transmitting device to stop transmitting the transmission signal.

The communication device realized at the sending end based on the virtual carrier data mode can realize the transmission of communication data by adopting the virtual carrier mode, has simple and convenient installation and lower cost, and improves the transmission efficiency of the communication data, thereby improving the use experience of users.

Corresponding to the communication method and device implemented at the sending end based on the virtual carrier data mode, the invention also provides a communication method and device implemented at the receiving end based on the virtual carrier data mode. Similar to the above method embodiment, the description is simple, and please refer to the description of the above method embodiment, and the communication method and apparatus implemented at the receiving end based on the virtual carrier data manner described below are only exemplary. As shown in fig. 3 and 4, which are a flowchart and a schematic diagram of a device of a communication method implemented at a receiving end based on a virtual carrier data manner according to an embodiment of the present invention, respectively.

The invention relates to a communication method realized at a receiving end based on a virtual carrier data mode, which comprises the following steps:

step S301: when the receiving end receives the target transmission signal transmitted by the communication method implemented based on the virtual carrier data manner, the control frequency number of the frequency oscillation module is accumulated by using the frequency counting module built in the receiving end.

The target transmission signal is a carrier signal (i.e. a transmission carrier such as a 2G communication signal or a 3G communication signal) having a starting point and an ending point, and a set of carrier characteristics or signals for identifying the start and the end of transmission are respectively set at the starting point and the ending point

Step S302: and when the frequency counting module accumulates to the end point of the target transmission signal, ending accumulating the control frequency number.

Step S303: and restoring the control frequency number corresponding to the target transmission signal from the starting point to the end point by using a frequency oscillation module arranged in the receiving end to obtain a restored transmission signal, and taking the restored transmission signal as an actual transmission signal of the transmitting end.

In the embodiment of the present invention, the receiving end may further obtain an actual control frequency number corresponding to the actual transmission signal accumulated by the frequency counting module; and calculating according to a preset algorithm based on the pre-calculated calibration coefficient and the actual control frequency number to obtain a calibrated actual transmission signal, and transmitting the calibrated actual transmission signal to a preset using module.

Specifically, the calibration coefficient may be calculated based on the received calibration signal of the pre-protocol and the calibration signal standard value of the pre-protocol (when the consecutive data packets are transmitted, the ratio of the actual frequency number of the previous data packet to the actual transmission signal after calibration is used as the calibration coefficient of the next data packet to achieve continuous dynamic calibration). Obtaining a data segment received by a receiving end and a control frequency number finally accumulated by a frequency counter built in the receiving end, sequentially measuring the sum of a tolerance and a tolerance of gyroscope acceleration calibration, carrying out weighted average calculation on a calibration coefficient, multiplying the sum by the control frequency number measured by a current frequency counter module, and then rounding to obtain calibrated data to be received and transmitting the calibrated data to a using unit, so that the problems of variation of a using environment, self heating of equipment and the like and precision deviation caused by frequency oscillation modules built in the transmitting end and the receiving end can be calibrated; other calibration review data may reference existing network communication protocols.

In the embodiment of the invention, the receiving end is internally provided with a receiving device, a built-in power supply module, a frequency oscillator module, a frequency counter module, a calibration module and the like. It should be noted that, in the case of being compatible with the existing wireless network according to different transmission media, a carrier characteristic or a signal that identifies the start point and the end point can be received in the existing network. The carrier characteristics or signals are typically represented in a carrier and received by the receiver. The implementation content of other transmission media is similar to the above process, and is not described in detail here. A counter for counting the number of oscillation frequencies of the built-in frequency oscillator during the process from the beginning to the end of the received signal; and a frequency algorithm calibration module.

The process of receiving data by the receiving end: a. the receiving device receives the control frequency number generated by the oscillation of the frequency oscillator module when the frequency counter module starts to accumulate when the transmission signal starts (when the receiving device is compatible with the existing carrier communication, the receiving device can start to accumulate the control frequency number when receiving the waveform characteristic or the signal representing the starting point); b. when the receiving device receives the end point of the continuous signal, the frequency counter ends accumulating the control frequency number (when the wave form characteristic or the signal representing the end point is received when the existing carrier communication is compatible, the accumulation of the control frequency number is started to be ended); the accumulated number is theoretically the data to be sent by the sending end; c. obtaining data segments received by a plurality of receiving ends in a time period and the control frequency number finally accumulated by the frequency counter module, carrying out weighted average calculation on a calibration coefficient according to the sum of the tolerance measured in sequence and the tolerance calibrated by the acceleration of the gyroscope, multiplying the calibration coefficient by the control frequency number measured by the current frequency counter module, and then rounding to obtain calibrated data to be received and transmitting the calibrated data to a using unit; therefore, the problems of the variation of the use environment, the variation of the self heating of the equipment and the like and the precision deviation caused by the built-in frequency oscillation modules of the sending end and the receiving end can be calibrated; other calibration review data may reference existing network communication protocols.

The processes a-b-c are repeatedly operated to realize the reception of a large number of data segments, and the processes of reception and transmission achieve the debugging and demodulation transmission of data virtual carrier data (virtual carrier frequency number). It should be noted that the sending end and the receiving end need to have frequency oscillators with the same frequency and achieve the time difference accuracy required correspondingly.

The communication method realized at the receiving end based on the virtual carrier data mode can realize the transmission of communication data by adopting the virtual carrier mode, is simple and convenient to install, not only expands the data communication mode, but also overcomes the defects of carrier wireless communication, reduces the cost of wireless communication and simultaneously improves the transmission efficiency of communication data.

The communication device realized at the receiving end based on the virtual carrier data mode comprises the following parts:

a frequency counting unit 401, configured to accumulate the control frequency number of the frequency oscillation module by using a frequency counting module built in the receiving end when the receiving end receives the target transmission signal transmitted by the communication method implemented based on the virtual carrier data manner according to claim 1. The target transmission signal is a carrier signal with a starting point and an ending point, and a group of carrier characteristics or signals for marking the start of transmission and the end of transmission are respectively set at the starting point and the ending point.

A frequency end counting unit 402, configured to end the accumulation of the control frequency number when the frequency counting module accumulates to the end point of the target transmission signal.

A restoring unit 403, configured to perform restoring processing on the control frequency number corresponding to the received target transmission signal from the starting point to the ending point by using a frequency oscillation module built in the receiving end, to obtain a restored transmission signal, and use the restored transmission signal as an actual transmission signal of the transmitting end.

The communication device realized at the receiving end based on the virtual carrier data mode can realize the transmission of communication data by adopting the virtual carrier mode, is simple and convenient to install, not only expands the data communication mode, but also overcomes the defects of carrier wireless communication, reduces the cost of wireless communication and simultaneously improves the transmission efficiency of communication data.

Corresponding to the two communication methods based on the virtual carrier data mode, the invention also provides a sending end communication system based on the virtual carrier data mode and a receiving end communication system based on the virtual carrier data mode. Since the embodiment of the communication system is similar to the above method embodiment, the description is relatively simple, and for the relevant points, reference may be made to the description of the above method embodiment, and the communication system described below is only schematic.

The invention relates to a transmitting end communication system realized based on a virtual carrier data mode, which comprises the following parts: the device comprises a built-in power supply module, a frequency oscillator module, a frequency counter module, a controller and an execution transmitting device. The built-in power supply module is used for providing electric energy for the frequency oscillator module, the frequency counter module, the controller and the execution transmitting device; the frequency oscillator module is used for modulating a data segment to be transmitted in a transmission signal with a starting point and an end point as oscillation frequency data; the transmission signal is a carrier signal with a starting point and an ending point, and carrier characteristics or signals used for starting and ending transmission of a group of identifiers are respectively set at the starting point and the ending point; the frequency counter module is used for accumulating the control frequency number which is generated by the frequency oscillation module and corresponds to the data segment to be sent; the controller is used for controlling the transmission signal to start or stop transmitting according to the time of the starting point and the ending point acquired by the frequency counter module; the execution sending device is used for starting sending the transmission signal or stopping sending the transmission signal according to the control signal which controls the transmission signal to start sending and end sending.

The invention relates to a receiving end communication system realized based on a virtual carrier data mode, which comprises the following parts: the device comprises a receiving device, a built-in power supply module, a frequency oscillator module, a frequency counter module and a calibration module. The built-in power supply module is used for providing electric energy for the receiving device, the frequency oscillator module, the frequency counter module and the calibration module; the receiving device is used for receiving a transmission signal sent by a sending end; the target transmission signal is a carrier signal with a starting point and an ending point, and carrier characteristics or signals for starting and ending transmission of a group of identifiers are respectively set at the starting point and the ending point; the frequency counter module is used for starting to accumulate control frequency numbers corresponding to the transmission signals after the receiving device receives the transmission signals sent by the sending end, and ending to accumulate the control frequency numbers when the control frequency numbers are accumulated to the end point of the target transmission signals; the frequency oscillation module is used for restoring the control frequency number accumulated by the frequency counter module to obtain an actual transmission signal; the calibration module is used for performing calibration processing on the actual transmission signal to obtain the calibrated actual transmission signal. The calibration module is further configured to calculate a calibration coefficient (when continuous data packets are transmitted, a ratio of an actual frequency number of a previous data packet to an actual transmission signal after calibration is used as a calibration coefficient of a subsequent data packet to achieve continuous dynamic calibration) from the received calibration signal of the previous protocol to the calibration signal standard value of the previous protocol.

Corresponding to the communication method realized based on the virtual carrier data mode, the invention also provides a computer storage medium. Since the embodiment of the computer storage medium is similar to the above method embodiment, the description is simple, and please refer to the description of the above method embodiment, and the computer storage medium described below is only schematic.

The computer storage medium contains one or more program instructions for executing the communication method implemented based on the virtual carrier data manner by the server.

The following detailed description is made on an embodiment of a storage method implemented based on a virtual carrier data manner according to the present invention, and the specific implementation process includes the following steps:

s501: and acquiring the data packet to be stored.

In the embodiment of the present invention, the data packet (or the data segment) may be directly used as a storage unit, and an arbitrary system (for example, the size of the data packet that can be stored is optimally converted into a most suitable system) may be used as a unit for storage. It is sufficient to record the start point and the end point of the data segment in the storage unit corresponding to the start point and the end point by using the data packet (or the data segment) as the storage unit (for example, consecutive 0 or consecutive 1, for example, 1Byet, i.e., 8bit, then he can store any number in 8-ary), and the data size of the data packet (or the data segment) corresponds to the number (position) of the start point and the end point in the storage unit. Further, the memory cell may be in other forms for being compatible with the existing memory cell, and is not limited herein. In addition, in the implementation process of the application, compared with the existing memory, an arbitrary binary encoder and an arbitrary decoder are required to be additionally arranged.

S502: controlling a data packet to record continuous signal marks in a storage unit according to a preset sequence by using a preset controller with a counter function, and recording the number of bits by taking the bits in the storage unit as a unit; when one bit is written in, controlling the counter to count once correspondingly, and when the number of writing times or the size of the data packet reaches or exceeds the preset number of writing times or the size of the data packet, starting to write in the subsequent data packet, and sequentially controlling the data of the subsequent data packet to be written in the storage unit; wherein the number of the bits is the data of the data packet; and each stored data packet is stored according to a preset system, and the preset system is stored by taking the size of the data packet as a system storage unit. Further, an arbitrary system converter may be provided to achieve; furthermore, bits in the storage unit are arranged, combined and counted, and the counter counts once correspondingly in each combination mode, so that the utilization rate of the storage medium can be increased; furthermore, the data packets may be compressed and decompressed in a binary system by writing a program or developing corresponding hardware (each data packet takes the size of the data packet as the binary system or a larger binary system, and the data packet is the maximum compression rate when being one of the binary systems by using a permutation and combination manner) for the storage, transmission, compression and decompression of the existing mechanism, and the reading of the data is performed on the contrary according to the storage, and thus, details are not repeated herein.

In the embodiment of the present invention, a controller with a counter function may be used to control a data packet (or a data segment) to sequentially record consecutive signal marks in a storage unit, where a bit (bit) in the storage unit is used as a unit, the number of recording bits is the data of the data packet (or the data segment) (for example, two binary sections 101, 1101, corresponding to decimal 5 and 13, are recorded, the control unit controls to write 5 consecutive sections 1 or 50, and the next data packet (or the data segment) is just inverted to 13 consecutive sections 0 or 1), and each time a bit is written, the counter counts once, and after the number of times of writing is required, the second data packet (or the data segment) is written, and the process of writing data in the storage unit is repeated. In the specific implementation process, because the utilization rate of the storage unit by the upper-level data writing is lower and is far lower than the existing binary 0 and 1 counting mode, the method for recording 1101 the data packet to be stored currently only needs 4 bits at minimum, but the data writing method expressed by the upper-level in the application needs 13 bits at minimum, and the larger the data volume of the data packet is, the lower the utilization rate of the storage unit is. Therefore, in order to improve the memory performance of the memory cell, a combined count storage method is extended, which includes the following steps:

a. 8-bit memory cells have 8 positions, each bit can store 1 or 0, and the conventional memory maximum data is 11111111, namely 255 in decimal. The eight bits are used for respectively arranging and combining the numbers 1 and 0, each combination represents a number, and then decoding and encoding operations (hereinafter referred to as combined decoding and encoding) are carried out through a de-encoder, so that the effect of optimizing the utilization rate of the storage unit can be achieved.

b. In the specific implementation process of the present application, through mathematical calculation, when the combined count storage method is extended, the 8-bit combinations may have 37 arrangement modes of 00000000, 01000000,. 01111111.. 10000000.. 11111111, 1010000.. 10111111, 10010000.. 100111111.... 10000001, and the mathematical calculation formula is: (8+1) × (8/2) +1 ═ 37, then any number from 1 to 37 decimal numbers can be stored in 8-bit memory, i.e. 100101 binary, so that only the capacity expansion of 8 decimal numbers (1000 binary) can be recorded for the data writing mode of the present patent.

c. The mathematical combination method is that the number of combinations increases geometrically, the data calculation method is (n +1) × (n/2) +1, and when the combinations are combined in units of 1k (1024 × 8 — 8192bit), and the memory utilization rate (8192+1) × (8192/2) +1 — 33558529 is observed, the decimal 3355829, i.e., the binary 1100110011010010110101, can be stored at maximum, and the increased utilization rate increases as the number of packets increases. In the specific implementation process, a combined decoding and encoder is added to the controller (controller with a counter and an arbitrary system encoder) at the previous stage for conversion, so that the application can be realized, and further description is omitted here.

It should be noted that the storage method according to the embodiment of the present application can compress and decompress various files in the existing system through programming. The existing storage system may also be modified and upgraded through hardware development, for example, by adding a relevant module to an existing hard disk, which is not described in detail herein.

In addition, for maximum utilization of storage, each stored data packet (or data segment) can be stored in a different scale, the scale of the maximum utilization is the size of the data packet (or data segment) itself as a scale storage unit, and the data of one data packet (or data segment) is a number in the scale.

By adopting the storage method realized based on the virtual carrier data mode, the utilization rate of the storage unit is extremely expanded, and a hardware realization method needs to develop a new related control module; the software implementation method needs to occupy system resources, but can realize different compression ratios according to different file sizes, the larger the compression ratio of the file is, and can establish a directory to achieve the operations of specified sequence, decompression and the like during decompression transmission according to different requirements of different files, and other operations can be performed while utilizing data during file decompression, for example, one movie data can be played while decompressing.

Corresponding to the storage method realized based on the virtual carrier data mode, the invention also provides a storage device realized based on the virtual carrier data mode. Since the embodiment of the apparatus is similar to the above method embodiment, the description is relatively simple, and please refer to the description of the above method embodiment, and the following description is only exemplary of an embodiment of a storage apparatus implemented based on a virtual carrier data method. The invention relates to a storage device realized based on a virtual carrier data mode, which comprises the following parts:

a data obtaining unit 601, configured to obtain a data packet to be stored.

A data storage unit 602, configured to utilize a preset controller with a counter function to control the data packet to record consecutive signal marks in the storage unit according to a preset sequence, and record the number of bits in units of bits in the storage unit; when one bit is written in, controlling the counter to count once correspondingly, and when the number of times of writing reaches or exceeds the preset number of times of writing, starting to write in the subsequent data packet, and sequentially controlling the data of the subsequent data packet to be written in the storage unit; wherein the number of the bits is the data of the data packet; and each stored data packet is stored according to a preset system, and the preset system is stored by taking the size of the data packet as a system storage unit. Further, an arbitrary system converter may be provided to achieve; furthermore, bits in the storage unit are arranged, combined and counted, and the counter counts once correspondingly in each combination mode, so that the utilization rate of the storage medium can be increased; furthermore, the data packets may be compressed and decompressed in a binary system by writing a program or developing corresponding hardware (each data packet takes the size of the data packet as the binary system or a larger binary system, and the data packet is the maximum compression rate when being one of the binary systems by using a permutation and combination manner) for the storage, transmission, compression and decompression of the existing mechanism, and the reading of the data is performed on the contrary according to the storage, and thus, details are not repeated herein.

In correspondence with the above-provided virtual carrier data manner-based storage method, the present invention also provides a computer-readable storage medium, containing one or more program instructions for a server to execute the virtual carrier data manner-based storage method according to claim 11; or the one or more program instructions are used for the server to execute the file that the data packet counts in any binary system and a plurality of virtual bits in an arrangement combination mode, and the file is stored and transmitted according to a compatible 0/1 file mode; the arrangement and combination mode of the plurality of virtual bits is the number of the virtual bits participating in data arrangement and combination set according to requirements; the server executes compression and decompression operations on various files in a software programming mode; the storage system is modified and upgraded in a hardware development mode; wherein, the modification and upgrade of the storage system comprises: a preset counter module, a system conversion module, a bit permutation and combination decoding module and an encoder are added in a hard disk for a storage system.

Specifically, since the utilization rate of the upper-level data writing to the storage unit is very low, which is much lower than the existing binary 0, 1 counting method, the existing method for recording 1101 this data packet only needs 4 bits at minimum, but the upper-level method needs 13 bits at minimum, and the larger the data amount of the data packet is, the less efficient the utilization rate of the storage unit is. In order to improve the storage efficiency of the memory cell, herein, a combination counting storage method is expanded, the specific principle is that there is a permutation and combination in mathematics, the storage method of the present patent can also use a permutation and combination form to improve the utilization rate of the memory cell, the current storage generally uses 8 bits as a unit for storage, and we firstly use 8 bits as a unit to make a principle and a method analysis by using the combination method, the specific principle is as follows:

1. the 8-bit storage unit has 8 positions, each bit can store 1 or 0, the traditional maximum storage data is 11111111, namely corresponding to 255 decimal, the numbers 1 and 0 are respectively arranged and combined by eight bits, each combination represents a number, and then decoding and encoding operations (hereinafter referred to as combined decoding and encoding) are carried out through a de-encoder, so that the effect of optimizing the utilization rate of the storage unit can be achieved.

2. By mathematical calculation, the 8-bit combination may have 37 arrangement modes of 00000000, 01000000,. 01111111.. 10000000.. 11111, 1010000.. 10111111, 10010000.. 100111111.. 10000001, and the mathematical calculation formula is: (8+1) × (8/4) +1 ═ 37, then any number from 1 to 37 decimal numbers can be stored in 8-bit memory, i.e. 100101 binary, so that only decimal 8 (multiples of 1000 binary extensions) can be recorded for the superior version of the patent.

3. The mathematical combination mode is that the number of combinations increases geometrically, the data calculation method is (n +1) × (n/2) +1, and if we combine in units of 1k (1024 × 8 ═ 8192bit), we can see the memory utilization rate (8192+1) × (8192/2) +1 ═ 33558529, we can store the decimal 3355829, that is, 1100110011010010110101 in binary form at maximum. Similarly, the maximum amount of memory can be calculated by 1kb memory, wherein 1kb is 1024 × 8 × 8388608 bits, and there can be (8388608+1) × 8388608/2+1 × 3.51843762831e +13 combinations, and a 4g memory can be stored as 4GB 4 × 1024 × 8 × 34359738368 bits at the maximum.

The combined mode of (34359738368+1) × 34359738368/2+1 ═ 5.90295810376e +20, and the data converted into the current mode are converted into the data to see how much the capacity can be reached, namely v5.90295810376e +20/8/1024/1024/1024 ═ 6871947674GB ═ 6710886.4TB ═ 6553.6P B. The memory utilization ratio of 4G can be obtained by the calculation, compared with the current memory mode, the memory utilization ratio can be improved to the maximum extent: 6871947676/4 is 1717986919 times greater, the greater the increased usage with larger packets

In the specific implementation process, a combined decoding and encoder is added into the controller (with a counter and an arbitrary system encoder) at the upper stage for conversion, so that the application can be realized. The storage method is implemented by the existing server through software programming into software, and can compress and decompress various files in the existing system; the storage method can be developed through hardware, and can be used for modifying and upgrading the existing storage system, for example, related modules are added into the existing hard disk.

The following describes an embodiment of a data calculation processing method implemented based on a virtual carrier data manner according to the present invention in detail. The specific implementation process comprises the following steps:

s701: receiving a data packet sent by a superior controller based on a preset instruction receiving module; wherein the data packet includes at least one of tuning data, temporary storage, accumulating data, and moving data.

S702: and converting the data packet into a data packet with the same system number based on a preset instruction controller containing an instruction set and a register.

S703: calculating the data packet by using a preset counter module in a superposition or superposition-subtraction calculation mode; wherein the counter module comprises an accumulation control counter module and/or an accumulation and reduction counter module.

In the embodiment of the present invention, the data calculation mode may be implemented by a data superposition (accumulation) mode and a superposition subtraction (accumulation subtraction) mode, which is similar to the abacus addition and subtraction principle and will not be described in detail herein.

In addition, a new instruction controller and a register containing a preset instruction set need to be designed, and the register can be arranged in the storage unit and can also be used for calling data into a special storage unit. And converting the two data packets into data packets with the same system number based on the instruction controller and the register, and overlapping or reducing the data packets by using a counter to achieve an addition and subtraction operation.

In the specific implementation process, the accumulation or subtraction method of the same-system data packets is as follows: a receivable instruction module, an increment control counter module, a decrement counter module, etc. are integrated on a controller of a data storage device storing data. The receivable instruction module is used for receiving calling data, temporary storage, accumulated data, accumulated and subtracted data, mobile data and the like sent by the superior controller.

It should be noted that, the calculation directly in the memory seems to be inefficient in operation speed, but distributed cluster calculation can be easily implemented, and the calculation is extended to trillion-level thread parallel calculation to achieve the effect of providing operation speed. By adopting the data calculation method, data can be simultaneously called to be applied to a special register and a special memory, virtual multithreading operation can be simultaneously carried out in a memory, a hard disk and even a U disk, and a multi-device cluster on a network can also process a single task or a plurality of tasks in a time division manner.

Corresponding to the data calculation processing method based on the virtual carrier data mode, the invention also provides a data calculation processing device based on the virtual carrier data mode. Since the embodiment of the apparatus is similar to the above method embodiment, the description is relatively simple, and please refer to the description of the above method embodiment, and the following description is only illustrative of an embodiment of the data calculation processing apparatus implemented based on the virtual carrier data manner. The data calculation processing device realized based on the virtual carrier data mode comprises the following parts:

a data receiving unit 801, configured to receive a data packet sent by a superior controller based on a preset instruction receiving module; wherein the data packet includes at least one of tuning data, temporary storage, accumulating data, and moving data.

And a data conversion unit 802, configured to convert the data packet into a data packet of the same carry based on a preset instruction controller and a register that include an instruction set.

A data processing unit 803, configured to perform calculation processing on the data packet by using a preset counter module in a superposition or subtraction calculation manner; wherein the counter module comprises an accumulation control counter module and/or an accumulation and reduction counter module.

In an embodiment of the present invention, the processor or the processing module may be an integrated circuit chip having signal processing capability. The Processor may be a general purpose Processor, a Digital Signal Processor (DSP), an Application Specific Integrated Circuit (ASIC), a Field Programmable Gate Array (FPGA) or other Programmable logic device, discrete Gate or transistor logic device, discrete hardware component.

The various methods, steps and logic blocks disclosed in the embodiments of the present invention may be implemented or performed. A general purpose processor may be a microprocessor or the processor may be any conventional processor or the like. The steps of the method disclosed in connection with the embodiments of the present invention may be directly implemented by a hardware decoding processor, or implemented by a combination of hardware and software modules in the decoding processor. The software module may be located in ram, flash memory, rom, prom, or eprom, registers, etc. storage media as is well known in the art. The processor reads the information in the storage medium and completes the steps of the method in combination with the hardware.

The storage medium may be a memory, for example, which may be volatile memory or nonvolatile memory, or which may include both volatile and nonvolatile memory.

The nonvolatile Memory may be a Read-Only Memory (ROM), a Programmable ROM (PROM), an Erasable PROM (EPROM), an Electrically Erasable PROM (EEPROM), or a flash Memory.

The volatile Memory may be a Random Access Memory (RAM) which serves as an external cache. By way of example and not limitation, many forms of RAM are available, such as Static random access memory (Static RAM, SRAM), Dynamic RAM (DRAM), Synchronous DRAM (SDRAM), Double Data Rate SDRAM (ddr Data Rate SDRAM), Enhanced SDRAM (ESDRAM), synclink DRAM (SLDRAM), and Direct memory bus RAM (DRRAM).

The storage media described in connection with the embodiments of the invention are intended to comprise, without being limited to, these and any other suitable types of memory.

Those skilled in the art will appreciate that the functionality described in the present invention may be implemented in a combination of hardware and software in one or more of the examples described above. When software is applied, the corresponding functionality may be stored on or transmitted over as one or more instructions or code on a computer-readable medium. Computer-readable media includes both computer storage media and communication media including any medium that facilitates transfer of a computer program from one place to another. A storage media may be any available media that can be accessed by a general purpose or special purpose computer.

The above-mentioned embodiments, objects, technical solutions and advantages of the present invention are further described in detail, it should be understood that the above-mentioned embodiments are only exemplary embodiments of the present invention, and are not intended to limit the scope of the present invention, and any modifications, equivalent substitutions, improvements and the like made on the basis of the technical solutions of the present invention should be included in the scope of the present invention.

Claims

1. A communication method realized based on a virtual carrier data mode is characterized by comprising the following steps:

extracting a data segment to be sent;

modulating the size of the data segment to be transmitted in a transmission signal with a starting point and an ending point as oscillation frequency data by using a frequency oscillation module arranged in a transmitting end; wherein the transmission signal comprises a transmission carrier of a continuous signal or a carrier signal;

and accumulating the control frequency number corresponding to the data segment to be transmitted, which is generated by the frequency oscillation module, by using a preset frequency counter module, obtaining a target transmission signal to be transmitted when the frequency counter module accumulates the control frequency number to be transmitted, and triggering a controller to control an execution transmitting device to stop transmitting the transmitted signal.

2. The communication method implemented based on the virtual carrier data scheme according to claim 1, further comprising: and respectively setting carrier characteristics or signals for one or more groups of combination identifications to start transmission and end transmission at the starting point and the end point during modulation.

3. The method of claim 1, wherein the transmission carrier comprises a conductor electrical signal and a radio wave signal.

4. A communication apparatus implemented based on a virtual carrier data scheme, comprising:

a data segment extraction unit, configured to extract a data segment to be sent;

the modulation unit is used for modulating the size of the data segment to be transmitted in a transmission signal with a starting point and an end point as oscillation frequency data by utilizing a frequency oscillation module arranged in a transmitting end; wherein the transmission signal comprises a transmission carrier of a continuous signal or a carrier signal;

and the frequency counting unit is used for accumulating the control frequency number corresponding to the data segment to be sent, which is generated by the frequency oscillation module, by using a preset frequency counter module, obtaining a target transmission signal to be sent when the frequency counter module accumulates the control frequency number to be sent, and triggering a controller to control and execute the sending device to stop sending the transmission signal.

5. A communication method realized based on a virtual carrier data mode is characterized by comprising the following steps:

when a receiving end receives a target transmission signal transmitted by the communication method realized based on the virtual carrier data mode according to claim 1, accumulating the control frequency number of the frequency oscillation module by using a frequency counting module built in the receiving end; the target transmission signal is a continuous or carrier signal with a starting point and an ending point, and carrier characteristics or signals for starting transmission and ending transmission of one or more groups of combined identifications are respectively set at the starting point and the ending point;

when the frequency counting module accumulates to the end point of the target transmission signal, ending accumulating the control frequency number;

and restoring the control frequency number corresponding to the target transmission signal from the starting point to the end point by using a frequency oscillation module arranged in the receiving end to obtain a restored transmission signal, and taking the restored transmission signal as an actual transmission signal of the transmitting end.

6. The method according to claim 5, further comprising:

acquiring the actual control frequency number corresponding to the actual transmission signal accumulated by the frequency counting module;

and obtaining a calibrated actual transmission signal based on a calibration coefficient calculated by a preset protocol calibration signal standard value and an actual control frequency number of the received calibration signal, and transmitting the calibrated actual transmission signal to a preset using module.

7. A communication apparatus implemented based on a virtual carrier data scheme, comprising:

a frequency counting unit, configured to accumulate the control frequency number of the frequency oscillation module by using a frequency counting module built in a receiving end when the receiving end receives a target transmission signal transmitted by the communication method implemented based on the virtual carrier data manner according to claim 1; the target transmission signal is a continuous signal or a carrier signal with a starting point and an ending point, and carrier characteristics or signals for starting transmission and ending transmission of one or more groups of combined identifications are respectively set at the starting point and the ending point;

the end frequency counting unit is used for ending the accumulation of the control frequency number when the frequency counting module accumulates to the end point of the target transmission signal;

a restoring unit, configured to restore a control frequency number corresponding to the received target transmission signal from the starting point to the ending point by using a frequency oscillation module built in the receiving end, to obtain a restored transmission signal, and use the restored transmission signal as an actual transmission signal of the transmitting end;

and the calibration unit is used for obtaining the actual control frequency number corresponding to the actual transmission signal accumulated by the frequency counting module, calculating a calibration coefficient calculated based on a preset protocol calibration signal standard value and the actual control frequency number of the received calibration signal, obtaining a calibrated actual transmission signal, and transmitting the calibrated actual transmission signal to a preset using module.

8. A transmitting end communication system realized based on a virtual carrier data mode is characterized by comprising the following components: the device comprises a built-in power supply module, a frequency oscillator module, a frequency counter module, a controller and an execution transmitting device;

9. A receiving end communication system realized based on a virtual carrier data mode is characterized by comprising the following components: the device comprises a receiving device, a built-in power supply module, a frequency oscillator module, a frequency metering module and a calibration module;

10. A computer readable storage medium containing one or more program instructions for execution by a server of a communication method implemented based on virtual carrier data according to any one of claims 1 to 3 or 5 to 6.

11. A storage method realized based on a virtual carrier data mode is characterized by comprising the following steps:

acquiring a data packet to be stored;

12. A storage device realized based on a virtual carrier data mode is characterized by comprising:

the data acquisition unit is used for acquiring a data packet to be stored;

13. A computer-readable storage medium containing one or more program instructions for executing the storage method implemented based on the virtual carrier data approach of claim 11 by a server; or the one or more program instructions are used for the server to execute the file that the data packet counts in any binary system and a plurality of virtual bits in an arrangement combination mode, and the file is stored and transmitted according to a compatible 0/1 file mode; the arrangement and combination mode of the plurality of virtual bits is the number of the virtual bits participating in data arrangement and combination set according to requirements;

the server executes compression and decompression operations on various files in a software programming mode; the storage system is modified and upgraded in a hardware development mode; wherein, the server refers to a computer system; the transformation and upgrade processing of the storage system comprises the following steps: a preset counter module, a system conversion module, a bit permutation and combination decoding module and an encoder are added in a hard disk for a storage system.

14. A data calculation processing method realized based on a virtual carrier data mode is characterized by comprising the following steps:

receiving a data packet sent by a superior controller based on a preset instruction receiving module; wherein the data packet includes at least one of tuning data, temporary storage, accumulation data, subtraction data, and movement data;

converting the data packet into a data packet with the same system number based on a preset instruction controller containing an instruction set and a register;

calculating the data packet by using a preset counter module in a superposition or superposition-subtraction calculation mode; wherein the counter module comprises an accumulation control counter module and/or an accumulation and reduction counter module.

15. A data calculation processing device realized based on a virtual carrier data mode is characterized by comprising:

the data receiving unit is used for receiving a data packet sent by the superior controller based on a preset instruction receiving module; wherein the data packet includes at least one of tuning data, temporary storage, accumulation data, subtraction data, and movement data;

the data conversion unit is used for converting the data packet into a data packet with the same system number based on a preset instruction controller containing an instruction set and a register;

the data processing unit is used for utilizing a preset counter module to calculate and process the data packet in a superposition or superposition-subtraction calculation mode; wherein the counter module comprises an accumulation control counter module and/or an accumulation and reduction counter module.