CN114935702B - IPG simulation test method, device, equipment and readable storage medium - Google Patents

Abstract

The application provides an IPG simulation test method, a device, equipment and a readable storage medium, wherein the method is applied to the IPG simulation test equipment and comprises the following steps: generating a virtual IPG for simulating a real IPG; before testing, obtaining a first parameter value of one or more equipment parameters of the virtual IPG; the device parameters include at least one of: signal strength, supply current, supply voltage, supply capacity, and device temperature; acquiring test information for testing the virtual IPG, and testing the virtual IPG according to the test information, wherein the test information is used for indicating parameter values of one or more test parameters; after the testing, a second parameter value of the one or more device parameters of the virtual IPG is obtained and displayed on a display device. The method and the device more accord with the test result of the real IPG under the test information by acquiring the parameter values before and after the virtual IPG test and displaying the second parameter value.

Description

IPG simulation test method, device, equipment and readable storage medium

Technical Field

The present application relates to the field of implantable medical devices, and in particular, to an IPG simulation test method, apparatus, device, and readable storage medium.

Background

In the technical field of Implantable medical devices, a programmable connection with an IPG (Implantable Pulse Generator) at a patient end is established through a programmer, and a doctor adjusts configuration information of the IPG through the programmer to realize adjustment of stimulation parameters of the IPG.

In the prior art, an IPG implanted in a patient is generally simulated by simulating a virtual patient and a virtual IPG. For example, patent CN110310736A discloses a data interaction method and system for an implantable medical programming device, the method includes: s1, adding a demonstration mode on a display interface of the program controller at the main control end; s2, establishing simulated communication data for the demonstration mode correspondingly according to the communication data of the original remote program control mode; s3, receiving an operation instruction in real time; if the operation instruction points to a remote program control mode entered by adopting a login mode, enabling the main control end program control instrument to perform data interaction with the remote implanted medical instrument through hardware connection in the remote program control mode; and if the operation instruction points to the demonstration mode, enabling the simulated master control end program controller to perform data interaction with the simulated remote implantable medical device through software simulated hardware equipment in the demonstration mode. The method can enable a doctor to select any type of IPG, can freely assign any parameter, and does not need to worry about the feeling of a patient. However, when the IPG is tested, the IPG simulated by the above method cannot obtain a test result conforming to the real IPG. This is because existing IPG simulation methods focus on the selection of simulated IPGs and the direct adjustment of parameters for the purpose of obtaining simulated patient feedback.

Therefore, it is highly desirable to design an IPG simulation test method to obtain a result more suitable for the real IPG test.

Disclosure of Invention

The application aims to provide an IPG simulation test method, an IPG simulation test device, an IPG simulation device and a computer readable storage medium, and a test result which is more in line with a real IPG is obtained through the simulation test of the IPG.

The purpose of the application is realized by adopting the following technical scheme:

in a first aspect, the present application provides an IPG simulation test method, which is applied to an IPG simulation test device, and the method includes: generating a virtual IPG for simulating a real IPG; before testing, obtaining a first parameter value of one or more equipment parameters of the virtual IPG; the device parameters include at least one of: signal strength, supply current, supply voltage, supply capacity, and device temperature; acquiring test information for testing the virtual IPG, and testing the virtual IPG according to the test information, wherein the test information is used for indicating parameter values of one or more test parameters; after the testing, a second parameter value of the one or more device parameters of the virtual IPG is obtained and displayed on a display device.

The technical scheme has the beneficial effects that: the virtual IPG is generated by simulating the real IPG, so that the real equipment parameters of the real IPG can be reflected. It can be understood that the obtained virtual IPG is tested in a targeted manner according to the test information, the tested second parameter value is obtained as a test result and is displayed, and the characteristics of the real IPG under the test information can be simulated and reflected. In one aspect, the virtual IPG is generated by simulating a real IPG, so that the virtual IPG is used for testing and can exhibit the same (second) parameter value as the real IPG; on the other hand, a first parameter value of the equipment parameter of the virtual IPG is obtained before the test, and the first parameter value can be used for adjusting the test information and the ratio of the second parameter value is equal, so that the aim of the IPG simulation test is stronger; on the other hand, since the IPG is used as a medical device, compared to other devices requiring professional certification or identification (for example, FDA-breakthrough medical device identification), the parameter values of interest in the simulation test of the IPG are also many different from those of other devices, and the signal strength, the supply current, the supply voltage, the supply capacity, and the device temperature are used as device parameters, so that the device is more targeted; in another aspect, the second parameter value of the device parameter is directly displayed on the display device, which facilitates the user to directly judge the test result of the virtual IPG.

In summary, a simulation test method applicable to the IPG is provided, which is different from the existing simulation program control and test of the IPG, so as to achieve the purpose of obtaining the simulation test feedback of the virtual IPG generated based on the real IPG, thereby realizing the simulation test of the virtual IPG generated based on the real IPG, and the obtained second parameter value better conforms to the test result of the real IPG under the test information.

In some optional embodiments, the test information comprises physician test information and/or development test information; the method further comprises the following steps: detecting whether a second parameter value of each equipment parameter is in a corresponding preset value range or not; if the second parameter value of each equipment parameter is in the corresponding preset value range, determining that the test information is applicable to the virtual IPG; determining that the test information is not applicable to the virtual IPG if a second parameter value of at least one of the device parameters is not within a corresponding preset range of values.

The technical scheme has the beneficial effects that: on one hand, whether the test information is suitable for the currently tested virtual IPG is judged by comparing the test information with a preset numerical range, and compared with other judgment modes, the method has the advantages of small calculation amount and convenience in judgment; on the other hand, a second parameter value obtained by the IPG simulation test is compared with a preset value range, so that a real IPG is not needed in the test process, and the cost is saved; on the other hand, when the second parameter value is not in the preset value range, the test information is not suitable for the virtual IPG, and a user can adjust the test information according to the result, so that the real IPG cannot be damaged due to the fact that the test information is not suitable, research and development cost is saved, and industrial popularization is facilitated; on the other hand, when the test information only comprises one of the doctor test information and the development test information, the data volume is small, and the pertinence is strong; on the other hand, when the test information simultaneously comprises the doctor test information and the development test information, more test functions can be realized, and a more comprehensive test result can be obtained.

In conclusion, the method can meet the requirements of doctors and developers respectively, the test information can comprise doctor test information and/or development test information, and the method has the advantages of configuration according to needs, high flexibility and strong pertinence.

In some optional embodiments, the determining that the test information is applicable to the virtual IPG if the second parameter value of each of the device parameters is within the corresponding preset value range includes: detecting whether the absolute value of the difference value between the first parameter value and the second parameter value of each equipment parameter is in a corresponding preset difference value range; if the absolute value of the difference value between the first parameter value and the second parameter value of each equipment parameter is in the corresponding preset difference value range, determining that the test information is applicable to the virtual IPG; the method further comprises the following steps: determining that the test information is not applicable to the virtual IPG if the absolute value of the difference between the first parameter value and the second parameter value of at least one of the device parameters is not within the corresponding preset difference range.

The technical scheme has the beneficial effects that: and comparing the absolute value of the difference value between the first parameter value and the second parameter value with a preset difference value range to obtain the applicability result of the test information and the virtual IPG, so that the reliability and the effectiveness of the test result are improved.

In some optional embodiments, the generating a virtual IPG for simulating a real IPG comprises: and generating the virtual IPG based on the calculation rule corresponding to each equipment parameter.

The technical scheme has the beneficial effects that: the virtual IPG generated by the calculation rule is more reasonable; when the user thinks that the generated virtual IPG and the simulated real IPG have difference, the calculation rule can be adjusted to eliminate the difference, each virtual IPG of the later-stage IPG simulation test does not need to be adjusted, and the intelligent degree is high.

In some optional embodiments, the process of obtaining the calculation rule corresponding to each device parameter includes: performing data mining by using historical data of a plurality of real IPGs to obtain a calculation rule corresponding to each equipment parameter; or when a first selection operation for one of the real IPGs is received, performing data mining by using the historical data of the selected real IPG to obtain a calculation rule corresponding to each equipment parameter.

The technical scheme has the beneficial effects that: data mining is carried out on historical data of a plurality of real IPGs, the corresponding relation among equipment parameters can be found, more information can be considered, and the generated virtual IPG is more reasonable; when historical data of a selected real IPG is mined, a virtual IPG for simulating and testing a real IPG of a specific model is generated, the data volume is small, the generation speed is high, and the pertinence of simulation testing is strong.

In some optional embodiments, the testing the virtual IPG according to the test information includes: and calculating real-time parameter values of one or more equipment parameters of the virtual IPG based on a calculation rule corresponding to one or more equipment parameters, and displaying the real-time parameter values on the display equipment.

The technical scheme has the beneficial effects that: acquiring data in the IPG simulation test process, so that a user can acquire the test condition which cannot be fed back by the second parameter value in real time through the display equipment, and the user can control the test process quantity in real time; the real-time parameter values of the equipment parameters are obtained based on the calculation rules, so that the real-time parameter values of the real IPG under the same test information can be simulated and displayed in real time, and the accuracy is high.

In some optional embodiments, the method further comprises: receiving, with the interactive device, a second selection operation for one or more of the device parameters to determine one or more of the device parameters that are updated in real-time.

The technical scheme has the beneficial effects that: receiving a second selection operation, determining one or more device parameters updated in real time, and displaying real-time parameter values of the one or more device parameters updated in real time on the display device. Therefore, partial or all equipment parameters can be updated in real time in a targeted manner according to the requirements of the user, so that the user can obtain not only the equipment parameters before and after the test, but also one or more equipment parameters in the process, the relevance among different equipment parameters can be obtained, and the simulation test efficiency of the user is improved.

In some alternative embodiments, the test parameters include one or more of: the voltage amplitude, frequency and pulse width of the stimulation pulse signal; the method comprises the following steps of (1) collecting a starting time, a collecting ending time and a collecting duration; and updating information of the program-controlled application, wherein the updating information comprises function updating information, display updating information and IPG permission updating range information.

The technical scheme has the beneficial effects that: one or more combinations of the test parameters can meet the requirements of different types of users on the IPG simulation test, and the practicability is high.

In a second aspect, the present application further provides an IPG simulation testing apparatus, which is applied to an IPG simulation testing device, the apparatus includes: the virtual IPG generation module is used for generating a virtual IPG used for simulating a real IPG; a first obtaining module, configured to obtain, before a test, a first parameter value of one or more device parameters of the virtual IPG; the device parameters include at least one of: signal strength, supply current, supply voltage, supply capacity, and device temperature; a test information acquisition module, configured to acquire test information used for testing the virtual IPG, and test the virtual IPG according to the test information, where the test information is used to indicate parameter values of one or more test parameters; and the second acquisition module is used for acquiring second parameter values of one or more equipment parameters of the virtual IPG after the test and displaying the second parameter values on the display equipment.

In some optional embodiments, the test information comprises physician test information and/or development test information; the device further comprises:

the first detection module is used for detecting whether a second parameter value of each equipment parameter is in a corresponding preset numerical range or not;

a first test determining module, configured to determine that the test information is applicable to the virtual IPG if a second parameter value of each of the device parameters is within a corresponding preset value range;

a second test determination module, configured to determine that the test information is not applicable to the virtual IPG if a second parameter value of the at least one device parameter is not within a corresponding preset value range.

In some optional embodiments, the first test determination module comprises:

a difference detection unit, configured to detect whether an absolute value of a difference between a first parameter value and a second parameter value of each of the device parameters is within a corresponding preset difference range;

a first test determining unit, configured to determine that the test information is applicable to the virtual IPG if an absolute value of a difference between a first parameter value and a second parameter value of each of the device parameters is within a corresponding preset difference range;

the device further comprises:

a third test determining module, configured to determine that the test information is not applicable to the virtual IPG if an absolute value of a difference between a first parameter value and a second parameter value of at least one of the device parameters is not within a corresponding preset difference range.

In some optional embodiments, the virtual IPG generation module includes:

and the virtual IPG generating unit is used for generating the virtual IPG based on the calculation rule corresponding to each equipment parameter.

In some optional embodiments, the process of obtaining the calculation rule corresponding to each device parameter includes:

carrying out data mining by using historical data of a plurality of real IPGs to obtain a calculation rule corresponding to each equipment parameter; alternatively, the first and second electrodes may be,

when a first selection operation aiming at one real IPG is received, data mining is carried out by utilizing the historical data of the selected real IPG so as to obtain a calculation rule corresponding to each equipment parameter.

In some optional embodiments, the test information obtaining module includes:

and the test information acquisition unit is used for calculating real-time parameter values of one or more equipment parameters of the virtual IPG based on a calculation rule corresponding to one or more equipment parameters and displaying the real-time parameter values on the display equipment.

In some optional embodiments, the apparatus further comprises:

a parameter validation module to receive, with the interactive device, a second selection operation for one or more of the device parameters to determine one or more of the device parameters to update in real-time.

In some alternative embodiments, the test parameters include one or more of:

the voltage amplitude, frequency and pulse width of the stimulation pulse signal;

the method comprises the following steps of (1) collecting a starting time, a collecting ending time and a collecting duration;

and updating information of the program-controlled application, wherein the updating information comprises function updating information, display updating information and IPG permission updating range information.

In a third aspect, the present application further provides an IPG simulation apparatus, where the IPG simulation apparatus includes a memory and a processor, where the memory stores a computer program, and the processor implements, when executing the computer program, the steps of the method in any one of the first aspects or the functions of the apparatus in any one of the second aspects.

In a fourth aspect, the present application further provides a computer-readable storage medium storing a computer program which, when executed by a processor, implements the steps of the method of any one of the first aspects or implements the functions of the apparatus of any one of the second aspects.

Drawings

The present application is further described below with reference to the drawings and examples.

Fig. 1 is a schematic flowchart of an IPG simulation testing method according to an embodiment of the present disclosure;

FIG. 2 is a schematic flow chart of yet another IPG simulation test method provided in the present application;

fig. 3 is a schematic flowchart illustrating a difference detection process of a virtual IPG according to the present application;

fig. 4 is a schematic structural diagram of an IPG simulation test apparatus provided in the present application;

FIG. 5 is a block diagram of an IPG simulation test apparatus provided in the present application;

fig. 6 is a schematic structural diagram of a program product for implementing an IPG simulation test method according to an embodiment of the present application.

Detailed Description

The present application is further described with reference to the accompanying drawings and the detailed description, and it should be noted that, in the present application, the embodiments or technical features described below may be arbitrarily combined to form a new embodiment without conflict.

The application area of the present application will first be briefly explained.

The (real) IPG may be provided in a patient for providing electrical stimulation, the stimulated biological tissue may be brain tissue of the patient, the stimulated site may be a specific site of the brain tissue, and the stimulated site may generally be different when the type of disease of the patient is different.

In reality, a (real) IPG implanted in a patient can be programmed through a program controller, and when the program controller and the IPG establish a program control connection, a user (including a doctor or a developer) can adjust parameters of an electrical stimulation signal of the IPG, can sense electrical activity in a deep brain of the patient through the IPG, and can guide the user to continuously adjust the parameters of the electrical stimulation signal of the IPG through the sensed electrical activity. The parameters of the electrical stimulation signal may be any of frequency (number of pulses per unit time 1s, in Hz), pulse width (duration of each pulse, in mus), and amplitude (typically expressed in voltage, i.e. the intensity of each pulse, in V).

In this embodiment, the IPG is simply called "implantable pulse generator" as it is not specifically stated, and in this embodiment, the implantable pulse generator may be a rechargeable pulse generator.

Referring to fig. 1, fig. 1 shows a schematic flow chart of an IPG simulation testing method provided in the present application.

The IPG simulation test method is applied to IPG simulation test equipment, and comprises the following steps:

step S101: generating a virtual IPG for simulating a real IPG;

step S102: before testing, obtaining a first parameter value of one or more equipment parameters of the virtual IPG; the device parameters include at least one of: signal strength, supply current, supply voltage, supply capacity, and device temperature;

step S103: acquiring test information for testing the virtual IPG, and testing the virtual IPG according to the test information, wherein the test information is used for indicating parameter values of one or more test parameters;

step S104: after the testing, a second parameter value of the one or more device parameters of the virtual IPG is obtained and displayed on a display device.

The virtual IPG is generated by simulating the real IPG, so that the real equipment parameters of the real IPG can be reflected. It can be understood that the obtained virtual IPG is tested in a targeted manner according to the test information, the tested second parameter value is obtained as a test result and is displayed, and the characteristics of the real IPG under the test information can be simulated and reflected.

Thus, on the one hand, the virtual IPG is generated by simulating a real IPG, so that the virtual IPG is used for testing and can exhibit the same (second) parameter value as the real IPG; on the other hand, a first parameter value of the equipment parameter of the virtual IPG is obtained before the test, and the first parameter value can be used for adjusting the test information and is equal to the second parameter value, so that the IPG simulation test is stronger in purpose; on the other hand, since the IPG is used as a medical device, compared to a general device, the IPG needs professional certification or identification (for example, FDA-breaking medical device identification), the parameter values of interest in the simulation test of the IPG are also many different from those of other devices, and the signal strength, the power supply current, the power supply voltage, the power supply capacity, and the device temperature are used as device parameters, so that the device is more targeted; in another aspect, the second parameter value of the device parameter is directly displayed on the display device, which facilitates the user to directly judge the test result of the virtual IPG.

In summary, a simulation test method applicable to the IPG is provided, which is different from the existing simulation program control and test of the IPG, so as to achieve the purpose of obtaining the simulation test feedback of the IPG, thereby realizing the simulation test of the virtual IPG generated based on the real IPG, and the obtained second parameter value better conforms to the test result of the real IPG under the test information.

The values of the signal strength, the supply current, the supply voltage, the supply capacity and the equipment temperature are not limited, and the parameter values of the signal strength are, for example, 10%, 20%, 0.2, 0.15, -70dbm or-40 dbm. The parameter value of the supply current is for example 75mA, 100mA or 1A. The parameter values of the supply voltage are for example 1VDC, 3VDC or 15 VDC. The parameter value of the supply capacity is for example 1000mAh, 700mAh or 600 mAh. The parameter values for the equipment temperature are for example 69 ° f, 60 ° f, 30 ℃ or 15 ℃.

The test information is used to indicate parameter values for one or more test parameters, such as: the test starting time, the test ending time, the voltage amplitude, the frequency and the pulse width of the stimulation pulse signal, the acquisition starting time, the acquisition ending time and the acquisition duration, the update information of the program control application and the like. The test information is not limited in the present application, and for example, the test information may be "voltage amplitude (2.8VDC), collection start time (collection after ten minutes), collection duration (collection 80 minutes), and collection end time (collection after 80 minutes)" of the stimulation pulse signal, and may also be "voltage amplitude (1.8VDC), current amplitude (11mA), test start time (1:15), and test end time (1: 58)" of the stimulation pulse signal.

In some optional embodiments, before or during the test, parameter values of one or more device parameters of the virtual IPG may also be obtained and displayed on a display device. And displaying the second parameter value on the display device until the test is completed. Therefore, the user can know whether the parameter value of the equipment parameter of the virtual IPG is correct or not, and the problems that invalid simulation test results appear and the simulation test time of the IPG is wasted due to deviation of the equipment parameter of the virtual IPG and the expected setting of the user are avoided.

Referring to fig. 2, fig. 2 is a schematic flow chart illustrating another IPG simulation testing method provided in the present application. In some alternative embodiments, the test information may include physician test information and/or development test information;

the method further comprises the following steps:

step S105: detecting whether a second parameter value of each equipment parameter is in a corresponding preset value range or not;

step S106: if the second parameter value of each equipment parameter is in the corresponding preset value range, determining that the test information is applicable to the virtual IPG;

step S107: determining that the test information is not applicable to the virtual IPG if a second parameter value of at least one of the device parameters is not within a corresponding preset range of values.

Therefore, on one hand, whether the test information is suitable for the currently tested virtual IPG is judged by comparing the test information with the preset numerical range, and compared with other judgment modes, the method is small in calculation amount and convenient to judge; on the other hand, the second parameter value obtained by the IPG simulation test is compared with the preset value range, so that a real IPG is not needed in the test process, and the cost is saved; on the other hand, when the second parameter value is not in the preset value range, the test information is not suitable for the virtual IPG, and the user can adjust the test information according to the result, so that the real IPG is not damaged due to the fact that the test information directly acts on the real IPG, research and development cost is saved, and industrial popularization is facilitated; on the other hand, when the test information only comprises one of the doctor test information and the development test information, the data volume is small, and the pertinence is strong; on the other hand, when the test information simultaneously comprises the doctor test information and the development test information, more test functions can be realized, and a more comprehensive test result can be obtained.

In conclusion, the method can meet the requirements of doctors and developers respectively, the test information can comprise doctor test information and/or development test information, and the method has the advantages of configuration according to needs, high flexibility and strong pertinence.

In a specific application, the doctor test information is considered to be suitable for the doctor to use the IPG simulation test method, for example: the "voltage amplitude (1.8VDC) of the stimulation pulse signal", "current amplitude (1mA) of the stimulation pulse signal" and the like are focused on test information tested by the doctor. As an example, when a doctor performs a test using the doctor test information containing the stimulation parameter configuration information, and finds that the virtual IPG consumes 90% of power in 2 hours, the doctor knows that the stimulation parameter configuration information is not suitable for the virtual IPG, and since the virtual IPG is generated by using a real IPG, the doctor can further know that the stimulation parameter configuration information cannot be used for programming the real IPG, which may cause the real IPG implanted in the patient to consume too fast power, require frequent charging, and have poor use experience.

In a specific application, it may be considered that the development test information is suitable for a developer to use an IPG simulation test method, and the development test information may be, for example, a code line, a code block, or the like. As one example, the development test information is version update code for realizing a function of "display font set to regular font", etc., focusing on development test.

The preset value range may be a value range preset by a user and corresponding to the device parameter. For example, the method comprises the following steps: (-50dbm, -10dbm), (7 ℃, 35 ℃) or (1mA, 12 mA).

In one specific application, when the preset value range is the signal strength (-40dbm, -30dbm), the equipment parameter is the signal strength, and the second parameter value is-35 dbm, the test information is determined to be suitable for the virtual IPG because the second parameter value of the signal strength is in the preset value range, and the IPG simulation test is completed.

In another specific application, the predetermined ranges of values are signal strength (-40dbm, -30dbm), device temperature (25 ℃, 35 ℃), device parameters are signal strength and device temperature, and the second values are-50 dbm and 30 ℃. While the parameter value of the device temperature is within its corresponding preset range of values, the parameter value of the signal strength is not within its corresponding preset range of values, in which case it is determined that the test information is not applicable to the virtual IPG.

Referring to fig. 3, fig. 3 is a schematic diagram illustrating a flow of difference detection for a virtual IPG provided in the present application. In some optional embodiments, the step S106 may include:

step S201: detecting whether the absolute value of the difference value between the first parameter value and the second parameter value of each equipment parameter is in a corresponding preset difference value range or not;

step S202: if the absolute value of the difference value between the first parameter value and the second parameter value of each equipment parameter is in the corresponding preset difference value range, determining that the test information is applicable to the virtual IPG;

the method may further comprise: determining that the test information is not applicable to the virtual IPG if the absolute value of the difference between the first parameter value and the second parameter value of at least one of the device parameters is not within the corresponding preset difference range.

Therefore, the test information and the applicability result of the virtual IPG are obtained by comparing the absolute value of the difference value between the first parameter value and the second parameter value with the preset difference value range, and the reliability and the effectiveness of the test result are improved.

Specifically, the judgment process of whether the test information is suitable for the virtual IPG is divided into two stages; the first stage judges whether the second parameter value is in a preset value range, and enters the second stage when the second parameter value is in the preset value range; and the second stage judges whether the absolute value of the difference between the first parameter value and the second parameter value is in the corresponding preset difference range, if so, the test information is determined to be applicable to the virtual IPG, otherwise, the test information is still considered to be not applicable to the virtual IPG. That is, only when the second parameter value itself and the comparison result between the second parameter value and the first parameter value are in the corresponding range, the "applicable" test result is obtained, otherwise, the "unsuitable" test result is obtained generally. The derivation of "applicable" results is very rigorous or even critical, since the test results of virtual IPGs are likely to be applied to real IPGs by physicians in the future, and therefore care is needed to ensure the life safety of patients.

In one specific application, the device parameter comprises a signal strength, and when the first parameter value comprises a signal strength of-31 dbm and the second parameter value comprises a signal strength of-39 dbm, the device parameter may correspond to a predetermined range of values for the signal strength of (-40dbm, -30dbm), and the first parameter value and the second parameter value for the signal strength may correspond to a predetermined range of differences of (1dbm, 3 dbm). Although the second parameter value of the signal strength is within the preset value range, the difference value of 8dbm between the first parameter value and the second parameter value is not within the preset difference value range, which can indicate that the parameter value in the IPG simulation test has large fluctuation, and the test information is not suitable for the virtual IPG.

In some optional embodiments, the step S101 may include: and generating the virtual IPG based on the calculation rule corresponding to each equipment parameter.

Therefore, the virtual IPG generated by the calculation rule is more reasonable; when the user thinks that the generated virtual IPG and the simulated real IPG have difference, the calculation rule can be adjusted to eliminate the difference, each virtual IPG of the later-stage IPG simulation test does not need to be adjusted, and the intelligent degree is high.

In other alternative embodiments, the step S101 may include: and generating the virtual IPG based on the calculation model corresponding to each equipment parameter.

In the embodiment of the present application, the term "generating a virtual IPG" refers to obtaining a non-solid model of a virtual IPG, where the virtual IPG has no solid structure, but has all the device parameters of a real IPG, and during a test process, the parameter values of the device parameters dynamically change in real time based on test information, and can be displayed in real time through a display device, which is similar to the observation of a real IPG, and allows a tester (including a doctor and a developer) to observe the real-time parameter values of each device parameter. Here, "similar to observing the real IPG" means that the real-time parameter values of the device parameters can be seen, and the data acquisition manner is also similar, the device parameters of the real IPG can be obtained only by communicating with the real IPG, and the device parameters of the virtual IPG can be obtained only by communicating with the virtual IPG.

The calculation rule and the calculation model may be obtained by performing data mining on historical data corresponding to the device parameters.

For the device parameter of the electric quantity, the corresponding historical data may include, for example: 5% of electricity is consumed for 1 hour in the stimulation mode; the electricity consumption is 3% when the device is used for 1 hour in the collection mode; the power consumption of 1 hour in the standby mode is 0.5 percent.

For the device parameter of signal strength, the corresponding historical data may include, for example: the signal intensity is 95% when the distance between the programmable device and the programmable device is 1 meter; the signal intensity is 90% when the distance between the programmable control equipment and the programmable control equipment is 3 meters; the signal intensity is 50% when the distance between the programmable device and the programmable device is 10 meters.

For the device parameter, i.e. the device temperature, the corresponding historical data may include, for example: heating to 0.05 ℃ for 1 hour in a stimulation mode; heating for 3 hours at 0.09 ℃ in a stimulation mode; the temperature is raised to 0.02 ℃ for 1 hour in the collection mode.

In some optional embodiments, the process of obtaining the calculation rule corresponding to each device parameter may include: carrying out data mining by using historical data of a plurality of real IPGs to obtain a calculation rule corresponding to each equipment parameter; alternatively, the first and second electrodes may be,

when a first selection operation aiming at one real IPG is received, data mining is carried out by utilizing the historical data of the selected real IPG so as to obtain a calculation rule corresponding to each equipment parameter.

Therefore, historical data of a plurality of real IPGs are subjected to data mining, the corresponding relation among equipment parameters can be found, more information can be considered, and the generated virtual IPG is more reasonable; when historical data of a selected real IPG is mined, a virtual IPG for simulating and testing a real IPG of a specific model is generated, the data volume is small, the generation speed is high, and the pertinence of simulation testing is strong.

The first selection operation may be a click, a frame selection, or a check performed by the user on a text, an icon, an image, or the like representing the real IPG through a keyboard, a mouse, a touch screen, or the like. For example, when the user clicks on the icons of the 1# real IP, the 2# real IPG, and the 3# real IPG, it means that data mining is performed on the history data of the 1# to 3# real IPGs.

The historical data can be experimental data and actual use data of the real IPG. For example, historical data of a real IPG is data that it has obtained after one week of real experiments in a laboratory. It can be considered that mining the historical data of the real IPG can obtain a calculation model or a calculation rule corresponding to the device parameter of the real IPG.

In some optional embodiments, the step S103 of testing the virtual IPG according to the test information may include:

and calculating real-time parameter values of one or more equipment parameters of the virtual IPG based on a calculation rule corresponding to one or more equipment parameters, and displaying the real-time parameter values on the display equipment.

Therefore, data in the IPG simulation test process are obtained, so that a user can obtain the test condition which cannot be fed back by the second parameter value in real time through the display equipment, and the user can control the test process quantity in real time; the real-time parameter values of the equipment parameters are obtained based on the calculation rules, so that the real-time parameter values of the real IPG under the same test information can be simulated and displayed in real time, and the accuracy is high.

In some optional embodiments, the method may further comprise: receiving, with the interactive device, a second selection operation for one or more of the device parameters to determine one or more of the device parameters that are updated in real-time.

Receiving a second selection operation, determining one or more device parameters updated in real time, and displaying real-time parameter values of the one or more device parameters updated in real time on the display device.

Therefore, partial or all equipment parameters can be updated in real time in a targeted manner according to the requirements of the user, so that the user can obtain not only the equipment parameters before and after the test, but also one or more equipment parameters in the process, the relevance among different equipment parameters can be obtained, and the simulation test efficiency of the user is improved.

The present embodiment does not limit the types of the interactive devices, such as a keyboard, a mouse, and a touch screen. And performing a second selection operation on one or more equipment parameters through the interactive equipment, determining parameter values of the selected equipment parameters and updating in real time.

In one specific application, the test is over half run, doctor a selects the signal strength through the touch screen, and the signal strength "90%" of the virtual IPG is updated and displayed on the display device in real time. Doctor A is satisfied with the current signal strength, and can terminate the test, so that the time for the IPG simulation test is saved. The test can be continued, so that the test result is more objective and accurate.

In another specific application, the test is over half, doctor B selects the signal strength through the touch screen, and the signal strength of the virtual IPG is updated in real time by "70%" and displayed on the display device. Doctor B is unsatisfactory to present signal intensity, and doctor B selects the equipment temperature through the touch-sensitive screen, and virtual IPG's equipment temperature "45 ℃ updates in real time and shows on display device, and doctor B can judge that the signal intensity that equipment temperature caused reduces. Therefore, doctor B can find the fundamental problem of the virtual IPG in the testing process conveniently.

In some alternative embodiments, the test parameters may include one or more of:

the voltage amplitude, frequency and pulse width of the stimulation pulse signal;

the method comprises the following steps of (1) collecting a starting time, a collecting ending time and a collecting duration;

and updating information of the program-controlled application, wherein the updating information comprises function updating information, display updating information and IPG permission updating range information.

Therefore, the combination of one or more of the test parameters can meet the requirements of different types of users on the IPG simulation test, and the practicability is high.

The embodiment does not limit the voltage amplitude, frequency, pulse width, acquisition start time, acquisition end time, acquisition duration and update information of the program control application. The voltage amplitudes in the above embodiment are, for example, 1V, 3V, 5V; frequencies are, for example, 130Hz, 110Hz, 100 Hz; the pulse width is, for example, 60. mu.s, 70. mu.s, 85. mu.s; the collection start time is, for example, "11: 00" or "after 1 hour"; the collection time period is, for example, "1 hour", "10 minutes", "50 seconds"; the acquisition end time is, for example, "13: 00", "16: 00", "18: 00"; the update information of the program control application is, for example, function update information such as "adding a timing stimulation function" and "adding a timing acquisition function"; the update information of the program-controlled application is also display update information such as "display UI is set to gray", "display font is set to song body", and the like; the update information of the program control application is IPG update permission range information such as "update IPG beginning with serial number 200" and "not update IPG beginning with serial number 100".

In one particular application, the user is a doctor a who is more concerned about changes in parameter values of signal strength, supply current, supply voltage, supply capacity, and device temperature of the real IPG in an application scenario in which the real IPG is applied to a patient. Thus, when the test parameters include one or more of the voltage amplitude, frequency, and pulse width of the stimulation pulse signal, a second parameter value of the virtual IPG may be obtained in an application scenario where the virtual IPG releases electrical stimulation in the patient.

In another specific application, the user is doctor B, which is more concerned about changes in parameter values of signal strength, supply current, supply voltage, supply capacity, and device temperature of the real IPG in an application scenario where the real IPG is applied to a patient. Thus, when the test parameters include one or more of the voltage amplitude, frequency and pulse width, acquisition start time, acquisition end time and acquisition duration of the stimulation pulse signal, the acquisition start time, acquisition end time and acquisition duration are used to instruct the IPG to acquire the test parameters of electrophysiological activity in the patient. A second parameter value of the virtual IPG may be obtained in an application scenario where the virtual IPG releases electrical stimulation and collects electrophysiological activity in the patient.

In yet another specific application, the user is a developer C, since the developer C is more concerned about changes in parameter values of signal strength, power supply current, power supply voltage, power supply capacity and device temperature of the real IPG in the application scene of system update and software adaptation. Thus, when the test parameters include updated information for the programmed application. And obtaining a second parameter value of the virtual IPG under the application scene of system updating and software adaptation of the virtual IPG.

Referring to fig. 4, fig. 4 is a schematic structural diagram illustrating an IPG simulation test apparatus provided in the present application. The embodiment of the application further provides an IPG simulation test device, which is applied to an IPG simulation test device, and an implementation manner of the IPG simulation test device is consistent with the implementation manner and the achieved technical effect recorded in the implementation manner of the method, and some contents are not repeated.

The device comprises:

a virtual IPG generation module 101, configured to generate a virtual IPG for simulating a real IPG;

a first obtaining module 102, configured to obtain, before a test, a first parameter value of one or more device parameters of the virtual IPG; the device parameters include at least one of: signal strength, supply current, supply voltage, supply capacity, and device temperature;

a test information obtaining module 103, configured to obtain test information used for testing the virtual IPG, and test the virtual IPG according to the test information, where the test information is used to indicate parameter values of one or more test parameters;

a second obtaining module 104, configured to obtain a second parameter value of the one or more device parameters of the virtual IPG after the test, and display the second parameter value on a display device.

In some alternative embodiments, the test information comprises physician test information and/or development test information; the device further comprises:

the first detection module is used for detecting whether a second parameter value of each equipment parameter is in a corresponding preset numerical range or not;

a first test determining module, configured to determine that the test information is applicable to the virtual IPG if a second parameter value of each of the device parameters is within a corresponding preset value range;

a second test determination module, configured to determine that the test information is not applicable to the virtual IPG if a second parameter value of the at least one device parameter is not within a corresponding preset value range.

In some optional embodiments, the first test determination module comprises:

a difference detection unit, configured to detect whether an absolute value of a difference between a first parameter value and a second parameter value of each of the device parameters is within a corresponding preset difference range;

a first test determining unit, configured to determine that the test information is applicable to the virtual IPG if an absolute value of a difference between a first parameter value and a second parameter value of each of the device parameters is within a corresponding preset difference range; the device further comprises:

a third test determining module, configured to determine that the test information is not applicable to the virtual IPG if an absolute value of a difference between a first parameter value and a second parameter value of at least one of the device parameters is not within a corresponding preset difference range.

In some optional embodiments, the virtual IPG generation module comprises:

and the virtual IPG generating unit is used for generating the virtual IPG based on the calculation rule corresponding to each equipment parameter.

In some optional embodiments, the process of obtaining the calculation rule corresponding to each of the device parameters includes:

carrying out data mining by using historical data of a plurality of real IPGs to obtain a calculation rule corresponding to each equipment parameter; alternatively, the first and second electrodes may be,

when a first selection operation aiming at one real IPG is received, data mining is carried out by utilizing the historical data of the selected real IPG so as to obtain a calculation rule corresponding to each equipment parameter.

In some optional embodiments, the test information obtaining module includes:

and the test information acquisition unit is used for calculating real-time parameter values of one or more equipment parameters of the virtual IPG based on a calculation rule corresponding to one or more equipment parameters and displaying the real-time parameter values on the display equipment.

In some optional embodiments, the apparatus further comprises:

a parameter validation module to receive, with the interactive device, a second selection operation for one or more of the device parameters to determine one or more of the device parameters to update in real-time.

In some alternative embodiments, the test parameters include one or more of:

the voltage amplitude, frequency and pulse width of the stimulation pulse signal;

the method comprises the following steps of (1) collecting a starting time, a collecting ending time and a collecting duration;

and updating information of the program-controlled application, wherein the updating information comprises function updating information, display updating information and IPG permission updating range information.

Referring to fig. 5, fig. 5 is a block diagram illustrating a structure of an IPG simulation test apparatus 200 according to the present invention. The IPG simulation test apparatus 200 includes at least one memory 210, at least one processor 220, and a bus 230 connecting different platform systems.

The memory 210 may include readable media in the form of volatile memory, such as Random Access Memory (RAM)211 and/or cache memory 212, and may further include Read Only Memory (ROM) 213.

The memory 210 further stores a computer program, and the computer program can be executed by the processor 220, so that the processor 220 implements the steps of any one of the methods, and the specific implementation manner of the method is consistent with the implementation manner and the achieved technical effect described in the implementation manner of the method, and some contents are not described again.

Memory 210 may also include a utility 214 having at least one program module 215, such program modules 215 including, but not limited to: an operating system, one or more application programs, other program modules, and program data, each of which, or some combination thereof, may comprise an implementation of a network environment.

Accordingly, the processor 220 may execute the computer programs described above, and may execute the utility 214.

The processor 220 may employ one or more Application Specific Integrated Circuits (ASICs), DSPs, Programmable Logic Devices (PLDs), Complex Programmable Logic Devices (CPLDs), Field-Programmable Gate arrays (FPGAs), or other electronic components.

Bus 230 may be one or more of any of several types of bus structures including a memory bus or memory controller, a peripheral bus, an accelerated graphics port, and a processor or local bus using any of a variety of bus architectures.

The IPG simulation test device 200 may also communicate with one or more external devices 240, such as a keyboard, pointing device, Bluetooth device, etc., and may also communicate with one or more devices capable of interacting with the IPG simulation test device 200, and/or with any device (e.g., router, modem, etc.) that enables the IPG simulation test device 200 to communicate with one or more other computing devices. Such communication may be through input-output interface 250. Also, the IPG simulation test device 200 may also communicate with one or more networks (e.g., a Local Area Network (LAN), a Wide Area Network (WAN), and/or a public network, such as the Internet) via the network adapter 260. The network adapter 260 may communicate with other modules of the IPG analog test device 200 via the bus 230. It should be understood that although not shown in the figures, other hardware and/or software modules may be used in conjunction with the IPG simulation test device 200, including but not limited to: microcode, device drivers, redundant processors, external disk drive arrays, RAID systems, tape drives, and data backup storage platforms, to name a few.

The present application further provides a computer-readable storage medium, where the computer-readable storage medium is used for storing a computer program, and when the computer program is executed, the steps of any one of the methods are implemented, and a specific implementation manner of the method is consistent with the implementation manner and the achieved technical effect described in the implementation manner of the method, and some details are not repeated.

Referring to fig. 6, fig. 6 is a schematic structural diagram illustrating a program product 300 for implementing an IPG simulation test method according to an embodiment of the present application.

Program product 300 may employ a portable compact disc read only memory (CD-ROM) and include program code and may run on a terminal device, such as a personal computer. However, the program product 300 of the present invention is not so limited, and in this application, a readable storage medium may be any tangible medium that can contain, or store a program for use by or in connection with an instruction execution system, apparatus, or device. Program product 300 may employ any combination of one or more readable media. The readable medium may be a readable signal medium or a readable storage medium. A readable storage medium may be, for example, but not limited to, an electronic, magnetic, optical, electromagnetic, infrared, or semiconductor system, apparatus, or device, or any combination of the foregoing. More specific examples (a non-exhaustive list) of the readable storage medium include: an electrical connection having one or more wires, a portable disk, a hard disk, a Random Access Memory (RAM), a read-only memory (ROM), an erasable programmable read-only memory (EPROM or flash memory), an optical fiber, a portable compact disc read-only memory (CD-ROM), an optical storage device, a magnetic storage device, or any suitable combination of the foregoing.

A computer readable storage medium may include a propagated data signal with readable program code embodied therein, for example, in baseband or as part of a carrier wave. Such a propagated data signal may take many forms, including, but not limited to, electro-magnetic, optical, or any suitable combination thereof. A readable storage medium may also be any readable medium that can communicate, propagate, or transport the program for use by or in connection with the instruction execution system, apparatus, or device. Program code embodied on a readable storage medium may be transmitted using any appropriate medium, including but not limited to wireless, wireline, optical fiber cable, RF, etc., or any suitable combination of the foregoing. Program code for carrying out operations for aspects of the present invention may be written in any combination of one or more programming languages, including an object oriented programming language such as Java, C + + or the like and conventional procedural programming languages, such as the C language or similar programming languages. The program code may execute entirely on the user's computing device, partly on the user's device, as a stand-alone software package, partly on the user's computing device and partly on a remote computing device, or entirely on the remote computing device or server. In the case of a remote computing device, the remote computing device may be connected to the user computing device through any kind of network, including a Local Area Network (LAN) or a Wide Area Network (WAN), or may be connected to an external computing device (e.g., through the internet using an internet service provider).

The terms "first," "second," "third," "fourth," and the like in the description and in the claims of the present application and in the drawings described above, if any, are used for distinguishing between similar elements and not necessarily for describing a particular sequential or chronological order. It is to be understood that the data so used is interchangeable under appropriate circumstances such that the embodiments of the application described herein are, for example, capable of operation in sequences other than those illustrated or otherwise described herein. Furthermore, the terms "comprises," "comprising," and "corresponding" and any variations thereof, are intended to cover a non-exclusive inclusion, such that a process, method, system, article, or apparatus that comprises a list of steps or elements is not necessarily limited to those steps or elements expressly listed, but may include other steps or elements not expressly listed or inherent to such process, method, article, or apparatus.

While the present application is described in terms of various aspects, including exemplary embodiments, the principles of the invention should not be limited to the disclosed embodiments, but are also intended to cover various modifications, equivalents, and alternatives falling within the spirit and scope of the invention as defined by the appended claims.

Claims (10)

1. An IPG simulation test method is applied to IPG simulation test equipment, and the method comprises the following steps:

generating a virtual IPG for simulating a real IPG;

before testing, obtaining a first parameter value of one or more equipment parameters of the virtual IPG; the device parameters include at least one of: signal strength, supply current, supply voltage, supply capacity, and device temperature;

acquiring test information for testing the virtual IPG, and testing the virtual IPG according to the test information, wherein the test information is used for indicating parameter values of one or more test parameters, and the test information comprises doctor test information and/or development test information;

after the test, obtaining a second parameter value of one or more equipment parameters of the virtual IPG and displaying the second parameter value on display equipment;

the method further comprises the following steps:

detecting whether a second parameter value of each equipment parameter is in a corresponding preset value range or not;

if the second parameter value of each equipment parameter is in the corresponding preset value range, determining that the test information is applicable to the virtual IPG;

determining that the test information is not applicable to the virtual IPG if a second parameter value of at least one of the device parameters is not within a corresponding predetermined range of values.

2. The IPG simulation testing method according to claim 1, wherein the determining that the test information is applicable to the virtual IPG if the second parameter value of each of the equipment parameters is within the corresponding preset value range comprises:

detecting whether the absolute value of the difference value between the first parameter value and the second parameter value of each equipment parameter is in a corresponding preset difference value range;

if the absolute value of the difference value between the first parameter value and the second parameter value of each equipment parameter is in the corresponding preset difference value range, determining that the test information is applicable to the virtual IPG;

the method further comprises the following steps:

determining that the test information is not applicable to the virtual IPG if the absolute value of the difference between the first parameter value and the second parameter value of at least one of the device parameters is not within the corresponding preset difference range.

3. The IPG simulation testing method according to claim 1, wherein said generating a virtual IPG for simulating a real IPG comprises:

and generating the virtual IPG based on the calculation rule corresponding to each equipment parameter.

4. The IPG simulation test method according to claim 3, wherein the process of obtaining the calculation rule corresponding to each of the equipment parameters comprises:

carrying out data mining by using historical data of a plurality of real IPGs to obtain a calculation rule corresponding to each equipment parameter; alternatively, the first and second electrodes may be,

when a first selection operation aiming at one real IPG is received, data mining is carried out by utilizing the historical data of the selected real IPG so as to obtain a calculation rule corresponding to each equipment parameter.

5. The IPG simulation test method of claim 4, wherein the testing the virtual IPG according to the test information comprises:

and calculating real-time parameter values of one or more equipment parameters of the virtual IPG based on a calculation rule corresponding to one or more equipment parameters, and displaying the real-time parameter values on the display equipment.

6. The IPG simulation testing method of claim 5, further comprising:

receiving, with the interactive device, a second selection operation for one or more of the device parameters to determine one or more of the device parameters that are updated in real-time.

7. The IPG simulation testing method according to claim 1, wherein the test parameters comprise one or more of:

the voltage amplitude, frequency and pulse width of the stimulation pulse signal;

the method comprises the following steps of (1) collecting a starting time, a collecting ending time and a collecting duration;

and updating information of the program-controlled application, wherein the updating information comprises function updating information, display updating information and IPG permission updating range information.

8. An IPG simulation test device, which is applied to IPG simulation test equipment, the device comprises:

the virtual IPG generation module is used for generating a virtual IPG used for simulating a real IPG;

a first obtaining module, configured to obtain, before a test, a first parameter value of one or more device parameters of the virtual IPG; the device parameter comprises at least one of: signal strength, supply current, supply voltage, supply capacity, and device temperature;

the test information acquisition module is used for acquiring test information for testing the virtual IPG and testing the virtual IPG according to the test information, wherein the test information is used for indicating parameter values of one or more test parameters, and the test information comprises doctor test information and/or development test information;

a second obtaining module, configured to obtain a second parameter value of the one or more device parameters of the virtual IPG after the test, and display the second parameter value on a display device;

the device further comprises:

the first detection module is used for detecting whether a second parameter value of each equipment parameter is in a corresponding preset numerical range or not;

a first test determining module, configured to determine that the test information is applicable to the virtual IPG if a second parameter value of each of the device parameters is within a corresponding preset value range;

a second test determination module, configured to determine that the test information is not applicable to the virtual IPG if a second parameter value of the at least one device parameter is not within a corresponding preset value range.

9. An IPG simulation apparatus comprising a memory and a processor, the memory storing a computer program, the processor implementing the steps of the method of any one of claims 1 to 7 when the computer program is executed by the processor.

10. A computer-readable storage medium, characterized in that the computer-readable storage medium stores a computer program which, when executed by a processor, performs the steps of the IPG simulation testing method of any one of claims 1 to 7.

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