CN116560454B - Pulse generation system - Google Patents

Abstract

The invention discloses a pulse generating system, in particular to the field of pulse signals, which comprises an input unit, a display unit, an output unit, a data conversion module and a data recording module, wherein the input unit is connected with the display unit; the input unit is configured for reception of pulse data; the display unit is configured for displaying the pulse data; the data conversion module is configured for converting pulse data; the output unit is configured for the generation of pulses; the data recording module is configured for recording and matching and checking pulse parameters, and after pulse signals are generated, the generated pulse signals can meet the requirements, so that the situation that the signal generation errors are large due to the fact that a traditional pulse generation signal system does not comprise any detection mechanism is avoided, the pulse signals are quickly generated by matching the pulse data and the pulse generation circuit data according to the acquired pulse parameter data before the pulse signals are generated, and meanwhile, the accuracy of pulse signal generation is improved.

Description

Pulse generation system

Technical Field

The invention relates to the field of pulse signals, in particular to a pulse generation system.

Background

Pulse generally refers to a short-term undulating electrical impulse like a pulse commonly used in electronics, with the main characteristics of waveform, amplitude, width and repetition frequency. Different pulse shapes can be generated by utilizing a pulse shaping program, and the optimal pulse shapes are different according to different applications;

Most of the existing pulse generation systems utilize a pulse generator or a pulse generation circuit to control and generate pulse signals directly according to pulse parameters;

However, the pulse generation efficiency in the prior art is low, the accuracy is poor, and the effective time of the pulse signal is within 1s, so that the pulse generation system has extremely high requirements on the generation time of the pulse signal, but the traditional pulse generation system does not have any measure for detection and correction, and meanwhile, the traditional pulse generation system can only generate signals according to parameters, and can not directly generate the pulse signal according to the past parameters, so that the pulse generation efficiency is low.

Disclosure of Invention

The invention aims to solve the defects in the prior art and provides a pulse generation system.

In order to achieve the above purpose, the present invention adopts the following technical scheme:

A pulse generating system comprises an input unit, a display unit, an output unit, a data conversion module and a data recording module;

the input unit is configured for reception of pulse data;

the display unit is configured for displaying pulse data;

The data conversion module is configured for converting pulse data;

the output unit is configured for the generation of pulses;

the data recording module is configured for recording and matching and checking pulse parameters.

Preferably, the input unit includes a data receiving module, a log module, a data checking module and a data uploading module, the data receiving module is configured for receiving data, the log module is configured for recording data receiving time, the data checking module is configured for checking data format, and the data uploading module is configured for uploading data.

The technical scheme is adopted: the past data is recorded and distributed according to time, so that the data can be more standard, and meanwhile, the data can be checked in advance, so that errors of pulse signals caused by non-uniform data formats in the later stage are avoided.

Preferably, the display unit includes a data receiving module, a data display module and a data uploading module, wherein the data receiving module is configured to receive the data processed by the input unit, the data display module is a touch display screen, and the data uploading module is configured to upload the data.

The technical scheme is adopted: the display unit can display the waveform of the pulse signal in real time, so that the observation is convenient.

Preferably, the output unit includes a data receiving module, a pulse generating circuit, a timing module and a data uploading module, wherein the data receiving module is configured to receive the data converted by the data converting module, the pulse generating circuit is configured to generate a pulse signal, the timing module is configured to limit the time of generating the pulse signal, and the data uploading module is configured to upload the data.

The technical scheme is adopted: the pulse generation circuit and the timing module are designed in the output unit, and the accuracy of pulse generation is effectively ensured by limiting the time of pulse generation.

Preferably, the output unit further comprises a circuit amplification detector configured for amplification detection of circuit data.

The technical scheme is adopted: the data parameters of the circuit in the pulse generation process are detected, so that a database can be filled, various parameters of the system in the pulse generation process are recorded, and the pulse generation efficiency is improved through big data.

Preferably, the data recording module comprises a primary parameter database, a secondary parameter database, a data calling module and a data matching module, wherein the primary parameter database and the secondary parameter database are configured for recording different parameter data, the data calling module is configured for calling data, and the data matching module is configured for matching data.

The technical scheme is adopted: the data recording module can be used for recording various data of the pulse generating system and is used for making a later data chart and improving the pulse generating efficiency, so that the system can be improved at any time.

Preferably, the specific flow of the data recording module is as follows: after the pulse signals are subjected to the calibration of the data integration calibration unit, the pulse parameter data received by the input unit and the converted parameter data are uploaded to a primary parameter database, circuit parameter data detected in the input unit when the pulse signals occur are uploaded to a secondary parameter database, when the pulse signals occur, the system receives the pulse signal parameter data from the outside, firstly, the parameter data are matched with the data in the primary parameter database, and after the matching is successful, the circuit parameters in the secondary parameter database can be retrieved, so that the rapid generation of the pulse signals is realized.

The technical scheme is adopted: by recording the pulse data and the pulse generation circuit data, the pulse signals can be matched in advance according to the acquired pulse parameter data before the pulse signals are generated, so that the rapid generation of the pulse signals is realized, and meanwhile, the accuracy of the generation of the pulse signals is improved.

Preferably, the generation of the pulse signal and the calibration flow in the system are as follows: the output unit generates pulse signals, the circuit amplification detector detects circuit data parameters, then the pulse signal data and the circuit parameter data are compared with the pulse signal parameters received by the input unit, the data can be integrated and checked within a certain error range, at the moment, the data are recorded to the data recording module, if the data do not pass, the data are returned to the data conversion module, and the pulse signals are generated again.

The technical scheme is adopted: after the pulse signal is generated, the generated pulse signal can be ensured to meet the requirement through calibration, and the condition that the signal generation error is large due to the fact that the traditional pulse generation signal system does not have any detection mechanism is avoided.

The beneficial effects of the invention are as follows:

1. The pulse signals are calibrated after the generation of the pulse signals, so that the generated pulse signals can meet the requirements, the situation that the signal generation errors are large due to the fact that a traditional pulse generation signal system does not comprise any detection mechanism is avoided, the pulse signals can be matched in advance according to the acquired pulse parameter data before the pulse signals are generated through recording the pulse data and the pulse generation circuit data, the rapid generation of the pulse signals is realized, and meanwhile the accuracy of the pulse signal generation is improved;

2. according to the invention, the data parameters of the circuit in the pulse generation process are detected, so that a database can be filled, and meanwhile, various parameters of a system in the pulse generation process are recorded, and the pulse generation efficiency is improved by using big data;

3. The invention records the past data and distributes the past data according to time, so that the data can be more standard, and the data can be checked in advance, thereby avoiding errors of pulse signals caused by non-uniform data formats in the later stage.

Drawings

FIG. 1 is a schematic diagram of a system flow in the present invention;

Fig. 2 is a system block diagram of the present invention.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments.

1-2, A pulse generating system comprises an input unit, a display unit, an output unit and a data recording module of a data conversion module;

the input unit is configured for reception of pulse data;

the display unit is configured for displaying pulse data;

The data conversion module is configured for converting pulse data;

the output unit is configured for the generation of pulses;

the data recording module is configured for recording and matching and checking pulse parameters.

The input unit comprises a data receiving module, a log module, a data checking module and a data uploading module, wherein the data receiving module is configured for receiving data, the log module is configured for recording data receiving time, the data checking module is configured for checking data formats, the data uploading module is configured for uploading data, recording the past data and distributing the past data according to time, the data can be more standard, and meanwhile, the data can be checked in advance, so that errors of pulse signals caused by non-uniform formats of the data in the later period are avoided.

The display unit comprises a data receiving module, a data display module and a data uploading module, wherein the data receiving module is configured to receive data processed by the input unit, the data display module is a touch display screen, the data uploading module is configured to upload data, and the display unit can display waveforms of pulse signals in real time, so that the observation is convenient.

The output unit comprises a data receiving module, a pulse generating circuit, a timing module and a data uploading module, wherein the data receiving module is configured for receiving the data converted by the data converting module, the pulse generating circuit is configured for generating pulse signals, the timing module is configured for limiting the time of the pulse signals, the data uploading module is configured for uploading the data, and the pulse generating circuit and the timing module are designed in the output unit, so that the accuracy of pulse generation is effectively ensured by limiting the time of the pulse generation.

The output unit also comprises a circuit amplification detector, wherein the circuit amplification detector is configured to amplify and detect circuit data, and can fill a database by detecting data parameters of the circuit in the pulse generation process, and simultaneously record various parameters of a system in the pulse generation process, so that the pulse generation efficiency is improved by using big data.

The data recording module comprises a primary parameter database, a secondary parameter database, a data calling module and a data matching module, wherein the primary parameter database and the secondary parameter database are configured to record different parameter data, the data calling module is configured to call data, the data matching module is configured to match data, the data recording module can be used for recording various data of the pulse generation system and for manufacturing later data icons and improving pulse generation efficiency, and the system can be improved at any time.

The specific flow of the data recording module is as follows: after the pulse signals are calibrated by the data integration and calibration unit, the pulse parameter data received by the input unit and the converted parameter data are uploaded to a primary parameter database, circuit parameter data detected in the input unit are uploaded to a secondary parameter database when the pulse signals occur, the system firstly matches the parameter data with data in the primary parameter database when the pulse signal parameter data from the outside are received, and after the matching is successful, circuit parameters in the secondary parameter database can be retrieved, so that the rapid generation of the pulse signals is realized, and by recording the pulse data and the pulse generation circuit data, the rapid generation of the pulse signals can be realized in advance according to the obtained pulse parameter data, and meanwhile, the accuracy of the pulse signal generation is improved.

The pulse signal generation and calibration flow in the system is as follows: the output unit generates pulse signals, the circuit amplification detector detects circuit data parameters, then pulse signal data and circuit parameter data are compared with the pulse signal parameters received by the input unit, the data can be integrated and checked within a certain error range, at the moment, the data are recorded to the data recording module, if the data are not passed, the data are returned to the data conversion module, the pulse signals are generated again, the generated pulse signals are checked after the pulse signals are generated, the generated pulse signals can meet the requirements, and the situation that the signal generation error is large because the traditional pulse generation signal system does not have any detection mechanism is avoided.

Working principle: the pulse generation flow of the invention is as follows:

S1, firstly, receiving parameter data of a required pulse signal, uploading the parameter data to an input unit, checking the format of the parameter by a data checking module in the input unit, and recording the receiving time of the data by a log module after the checking is completed;

S2, converting the format of the data processed by the input module through a data conversion module;

S3, matching data: inputting the converted parameter data into a value data recording module, matching the parameter data with data in a primary parameter database through a data matching module, calling the data in a secondary parameter database through a data calling module when the matching is successful, and inputting the called parameter data into an output module to finish the generation of pulse signals;

When the matching fails, the converted data parameters are uploaded to an input module, a pulse generating circuit in an output unit generates pulse signals, and meanwhile, a timing module limits the time for the pulse generating circuit to generate the pulse signals;

S4, the data passes through a data integration and correction unit, if the data passes through the data integration and correction unit, the data is returned to the data conversion module, and the generation of the pulse signal is performed again;

if the calibration is passed, the pulse signal parameter data and the circuit parameter data are respectively uploaded to a primary parameter database and a secondary parameter database, so that the whole pulse generation process is completed.

The foregoing is only a preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art, who is within the scope of the present invention, should make equivalent substitutions or modifications according to the technical scheme of the present invention and the inventive concept thereof, and should be covered by the scope of the present invention.

Claims (1)

1. The pulse generation system is characterized by comprising an input unit, a display unit, an output unit, a data conversion module and a data recording module;

the input unit is configured for reception of pulse data;

the display unit is configured for displaying pulse data;

The data conversion module is configured for converting pulse data;

the output unit is configured for the generation of pulses;

The data recording module is configured for recording and matching and checking pulse parameters;

The input unit comprises a data receiving module, a log module, a data checking module and a data uploading module, wherein the data receiving module is configured for receiving data, the log module is configured for recording data receiving time, the data checking module is configured for checking data formats, the data uploading module is configured for uploading data, recording past data and distributing the past data according to time;

The display unit comprises a data receiving module, a data display module and a data uploading module, wherein the data receiving module is configured to receive the data processed by the input unit, the data display module is a touch display screen, the data uploading module is configured to upload the data, and the display unit can display waveforms generated by pulse signals in real time;

the output unit comprises a data receiving module, a pulse generating circuit, a timing module and a data uploading module, wherein the data receiving module is configured for receiving the data converted by the data converting module, the pulse generating circuit is configured for generating a pulse signal, the timing module is configured for limiting the time of generating the pulse signal, and the data uploading module is configured for uploading the data;

The output unit further comprises a circuit amplification detector configured for amplification detection of circuit data;

The data recording module comprises a primary parameter database, a secondary parameter database, a data calling module and a data matching module, wherein the primary parameter database and the secondary parameter database are configured for recording different parameter data, the data calling module is configured for calling data, and the data matching module is configured for matching data;

The specific flow of the data recording module is as follows: after the pulse signals are subjected to the calibration of the data integration and calibration unit, the pulse parameter data received by the input unit and the converted parameter data are uploaded to a primary parameter database, circuit parameter data detected in the input unit when the pulse signals occur are uploaded to a secondary parameter database, when the pulse signals occur, the system receives the pulse signal parameter data from the outside, firstly, the parameter data are matched with the data in the primary parameter database, and after the matching is successful, the circuit parameters in the secondary parameter database can be called, so that the rapid generation of the pulse signals is realized;

The generation of pulse signals in the system and the checking flow are as follows: the output unit generates pulse signals, the circuit amplification detector detects circuit data parameters, then the pulse signal data and the circuit parameter data are compared with the pulse signal parameters received by the input unit, the data can be integrated and checked within a certain error range, at the moment, the data are recorded to the data recording module, if the data do not pass, the data are returned to the data conversion module, and the pulse signals are generated again.