CN117711239A - Method and device for testing and displaying physiological data by combining virtual reality with control panel - Google Patents

Abstract

The invention provides a physiological data testing and displaying method and device of a virtual reality combined control panel, which can adjust task difficulty, simulate and display the world in a VR mode to stimulate physiological sense organs and automatically store physiological sense organ data. The invention builds a helicopter simulator system by accessing peripheral physiological monitoring equipment data based on a computer virtual reality technology, provides a repeatedly operated software platform for a pilot, performs multi-task and multi-parameter task simulation in the platform, collects physiological and psychological data generated by the pilot under different scenes and task situations, and calculates the collected data to form the data capable of being ground.

Description

Method and device for testing and displaying physiological data by combining virtual reality with control panel

Technical Field

The invention relates to the technical field of physiological testing, in particular to a physiological data testing display method and device of a virtual reality combined control panel.

Background

Under the condition that the technology of China breaks through continuously, along with the update iteration of multiple models, multiple functions and multiple purposes of the helicopter, the problems of complex operation, difficult training, difficult mastering, and the like of the helicopter are brought, the requirements of the pilot skill are improved continuously by combining the factors, the helicopter simulator system is built by accessing peripheral physiological monitoring equipment data based on the computer virtual reality technology, and the problem to be solved is that a repeatedly operated software platform is provided for the pilot

Disclosure of Invention

The present invention is directed to a method and apparatus for displaying a physiological data test of a virtual reality-combined control panel that overcomes or at least partially solves the above-mentioned problems.

In order to achieve the above purpose, the technical scheme of the invention is specifically realized as follows:

one aspect of the present invention provides a physiological data test display method of a virtual reality combined control panel, including: performing multi-ship-based helicopter simulation by using a real-time rendering technology; adjusting the difficulty of a control task; and collecting and displaying the physiological data of the trainee.

The multi-ship-based helicopter simulation by using the real-time rendering technology comprises the following steps: simulating a marine scene, simulating a ship-based helicopter and simulating a plurality of ships; wherein:

the simulating of the ocean scene comprises:

using a loader to manufacture ocean effects;

simulating sea level fluctuation, foam system and helicopter offshore ripple based on a fast Fourier transform method;

adjusting a loader language parameter and changing the sea surface effect;

the simulating of the ship-based helicopter comprises the following steps:

based on the Unity physical system and the animation system, a helicopter flight script is manufactured and controlled;

under a fixed mode, controlling the helicopter to complete a flight task and act and recording the Transform information; storing the task action as an resolver file, and reproducing the task action by combining the resolver file with a helicopter model;

under the free mode, based on the operation script, a VR control helicopter script is manufactured, and the VR handle is combined for control;

the simulating the multi-ship comprises the following steps: based on 3Dmax, manufacturing a simulated ship model; and (3) manufacturing a preliminary model, displaying UV according to the performance and the number of the reduced surfaces, mapping, and baking by using a Unity rendering pipeline to finish the multi-ship simulation.

Wherein the task difficulty comprises a difficult mode, a simple mode and a free mode; the adjusting and controlling task difficulty comprises the following steps: adjusting the difficulty parameter adjusts the task difficulty.

Wherein, gather and display training person's physiological data include: adjusting the task speed; executing a task and a task action; the physiological sensor is used for collecting physiological data in the task executing process of the trainer; the physiological data of the trainer in the training process are displayed in real time.

Wherein the method further comprises: and constructing a database, and storing physiological data of a trainer into the database to form a training data set when task simulation is performed each time.

Another aspect of the present invention provides a physiological data test display apparatus of a virtual reality-combined control panel, including: the simulation module is used for simulating the multi-ship-based helicopter by utilizing a real-time rendering technology; the adjusting module is used for adjusting the difficulty of the control task; and the acquisition module is used for acquiring and displaying physiological data of a trainer.

The simulation uses a real-time rendering technology to simulate the multi-ship-based helicopter in the following manner: simulating a marine scene, simulating a ship-based helicopter and simulating a plurality of ships; wherein:

the simulating of the ocean scene comprises:

using a loader to manufacture ocean effects;

simulating sea level fluctuation, foam system and helicopter offshore ripple based on a fast Fourier transform method;

adjusting a loader language parameter and changing the sea surface effect;

the simulating of the ship-based helicopter comprises the following steps:

based on the Unity physical system and the animation system, a helicopter flight script is manufactured and controlled;

under a fixed mode, controlling the helicopter to complete a flight task and act and recording the Transform information; storing the task action as an resolver file, and reproducing the task action by combining the resolver file with a helicopter model;

under the free mode, based on the operation script, a VR control helicopter script is manufactured, and the VR handle is combined for control;

the simulating the multi-ship comprises the following steps: based on 3Dmax, manufacturing a simulated ship model; and (3) manufacturing a preliminary model, displaying UV according to the performance and the number of the reduced surfaces, mapping, and baking by using a Unity rendering pipeline to finish the multi-ship simulation.

Wherein the task difficulty comprises a difficult mode, a simple mode and a free mode; the adjusting module adjusts the difficulty of the control task in the following way: adjusting the difficulty parameter adjusts the task difficulty.

The acquisition module acquires and displays physiological data of a trainer in the following mode: adjusting the task speed; executing a task and a task action; the physiological sensor is used for collecting physiological data in the task executing process of the trainer; the physiological data of the trainer in the training process are displayed in real time.

Wherein the apparatus further comprises: a storage module; the storage module is used for constructing a database, and storing physiological data of a trainer into the database to form a training data set when task simulation is carried out each time.

Therefore, the physiological data testing and displaying method and device of the virtual reality combined control panel can adjust task difficulty, simulate and display the world in a VR mode to stimulate physiological sense organs, and automatically store physiological sense organ data. The invention builds a helicopter simulator system by accessing peripheral physiological monitoring equipment data based on a computer virtual reality technology, provides a repeatedly operated software platform for a pilot, performs multi-task and multi-parameter task simulation in the platform, collects physiological and psychological data generated by the pilot under different scenes and task situations, and calculates the collected data to form the data capable of being ground.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings that are needed in the description of the embodiments will be briefly described below, it being obvious that the drawings in the following description are only some embodiments of the present invention, and that other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

Fig. 1 is a flowchart of a method for displaying physiological data test of a virtual reality combined control panel according to an embodiment of the present invention;

fig. 2 is a specific flowchart of a method for displaying physiological data test of a virtual reality combined control panel according to an embodiment of the present invention;

FIG. 3 is a flow chart of a simulation of a multi-ship carrier-based helicopter provided by an embodiment of the invention;

fig. 4 is a schematic structural diagram of a physiological data testing display device with a virtual reality combined with a control panel according to an embodiment of the present invention.

Detailed Description

Exemplary embodiments of the present disclosure will be described in more detail below with reference to the accompanying drawings. While exemplary embodiments of the present disclosure are shown in the drawings, it should be understood that the present disclosure may be embodied in various forms and should not be limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the scope of the disclosure to those skilled in the art.

Fig. 1 shows a flowchart of a physiological data test display method of a virtual reality combined control panel provided by an embodiment of the present invention, fig. 2 shows a specific flowchart of a physiological data test display method of a virtual reality combined control panel provided by an embodiment of the present invention, and referring to fig. 1 and fig. 2, the physiological data test display method of a virtual reality combined control panel provided by an embodiment of the present invention includes:

s1, performing multi-ship-based helicopter simulation by using a real-time rendering technology.

Specifically, the invention adopts advanced real-time rendering technology to restore real ocean and space environment. The multi-ship is deployed in the environment, the arrangement of the ships is carried out according to the real tasks, the ship supports the helicopter to lift and lower, and the flying environment of the helicopter is simulated. The helicopter and the ship are modeled by referring to the appearance and the interior trim of the real model, and the flight view angle in the cabin of the helicopter is restored. The flight control refers to the flight data production of a real helicopter, restores the flight behavior of the helicopter, and restores the feeling of the helicopter on the pilot by combining a six-degree-of-freedom platform, the flight attitude, the gravity and the like. The helicopter flight sound effects are recorded in real time, and the helicopter flight sound effects at different rotating speeds are simulated through the audio technologies such as pitch adjustment, multi-track synthesis and the like, so that the sound effect changes in the states of engine starting, stopping, accelerating, decelerating and the like can be restored. The whole helicopter carries out simulation on the flying of the carrier-borne helicopter under the multi-ship from the aspects of vision, scene, feeling, operation, sound effect and the like.

Before the physiological data is tested and acquired, the invention performs view building work including, but not limited to, VR helmet adaptation program, VR device environment building and selected rendering pipeline (identified as URP rendering pipeline).

As an alternative implementation manner of the embodiment of the present invention, when performing high fidelity multi-ship-based helicopter simulation specifically, referring to fig. 3, the performing multi-ship-based helicopter simulation by using a real-time rendering technique includes: simulating a marine scene, simulating a ship-based helicopter and simulating a plurality of ships; wherein:

simulating the ocean scene includes:

using a loader to manufacture ocean effects;

simulating sea level fluctuation, foam system and helicopter offshore ripple based on a fast Fourier transform method;

adjusting a loader language parameter and changing the sea surface effect;

simulating the carrier-based helicopter includes:

based on the Unity physical system and the animation system, a helicopter flight script is manufactured and controlled;

under a fixed mode, controlling the helicopter to complete a flight task and act and recording the Transform information; storing the task action as an resolver file, and reproducing the task action by combining the resolver file with a helicopter model;

under the free mode, based on the operation script, a VR control helicopter script is manufactured, and the VR handle is combined for control;

simulating the multi-vessel comprises: based on 3Dmax, manufacturing a simulated ship model; and (3) manufacturing a preliminary model, displaying UV according to the performance and the number of the reduced surfaces, mapping, and baking by using a Unity rendering pipeline to finish the multi-ship simulation.

S2, adjusting the difficulty of the control task.

As an alternative to the embodiments of the present invention, task difficulties include difficult, simple and free modes; adjusting the control task difficulty includes: adjusting the difficulty parameter adjusts the task difficulty.

Specifically, the helicopter flight tasks design helicopter simulation operation according to real flight tasks of aircraft carriers, amphibious attack vessels and expulsion vessels and referring to different vessels respectively, and three independent different helicopter operation tasks are designed, wherein each task is different in difficulty. In the fixed mode, each task is adjustable by a plurality of difficulty parameters, and each stage of the task can set the difficulty parameters to adjust the difficulty of the task.

The physiological state of the tested person can be stimulated by means of the adjustable action of the sliding bar and the task speed.

S3, collecting and displaying physiological data of the trainee.

As an alternative implementation of the embodiment of the present invention, the collecting and displaying the physiological data of the trainer includes: adjusting the task speed; executing a task and a task action; the physiological sensor is used for collecting physiological data in the task executing process of the trainer; the physiological data of the trainer in the training process are displayed in real time.

Specifically, the trainer wears a plurality of physiological sensors, synchronously measures and collects heart rhythm, skin electric response signals, electromyographic signals, heart rate, blood oxygen saturation and skin temperature of the trainer, and records the heart rhythm, skin electric response signals, electromyographic signals, heart rate, blood oxygen saturation and skin temperature in real time in the helicopter operation simulation training process. The system comprises a main control console, and can check all physiological data of a trainer in the training process and check real-time changes of the physiological data.

As an optional implementation manner of the embodiment of the present invention, the method for testing and displaying physiological data of a virtual reality combined control panel provided by the embodiment of the present invention further includes: and constructing a database, and storing physiological data of a trainer into the database to form a training data set when performing task simulation each time.

Specifically, a heart generating database is constructed, and when an operator performs task simulation each time, the system stores physiological and psychological data of a trainer into the database to form a training data set, and the training data can be derived from the data set, so that follow-up study is facilitated.

When the physiological data are tested by using the physiological testing equipment, the physiological data of the tested person are stimulated by combining the VR vision and the main control UI, after the tested person wears the physiological sensor, the tested person wears VR glasses, the testing and management person clicks and selects the test items on the computer screen through a mouse, the selection difficulty is set, different task action speeds are set to stimulate the physiological and psychological states of the tested person, and the physiological information of the tested person is returned to the port set by the software through the port and is displayed on the screen after being processed. After the test is finished, the physiological change data in the tested process is automatically stored.

The specific operation flow is as follows:

1. the testers carry physiological sensors and VR head display equipment.

2. Starting a test program, selecting a task scene (amphibious attack ship, aircraft carrier, and expulsion ship), setting task difficulty (fixing and difficulty), and setting a speed interval (1-30) of each action (anti-diving, take-off, landing, sliding down, steering, horizontal movement and the like).

3. Clicking to start the task after the setting is completed, and executing the task.

4. The software automatically records and displays the information (blood oxygen saturation, heart rhythm, myoelectricity, skin electricity, skin temperature) returned by the physiological sensor in the form of a dynamic line graph.

5. After the task execution is completed, the file is automatically stored and exported to the desktop in software.

Therefore, by the method for testing and displaying the physiological data of the virtual reality combined with the control panel, which is provided by the embodiment of the invention, the task difficulty can be regulated, the world is simulated and displayed in a VR mode to stimulate physiological sense organs, and the physiological sense organ data is automatically stored. The invention builds a helicopter simulator system by accessing peripheral physiological monitoring equipment data based on a computer virtual reality technology, provides a repeatedly operated software platform for a pilot, performs multi-task and multi-parameter task simulation in the platform, collects physiological and psychological data generated by the pilot under different scenes and task situations, and calculates the collected data to form the data capable of being ground.

Fig. 4 is a schematic structural diagram of a physiological data testing display device of a virtual reality combined control panel according to an embodiment of the present invention, where the physiological data testing display device of a virtual reality combined control panel applies the above method, and the following only briefly describes the structure of the physiological data testing display device of a virtual reality combined control panel, and other less-than-anything, please refer to the related description in the physiological data testing display method of a virtual reality combined control panel, referring to fig. 4, where the physiological data testing display device of a virtual reality combined control panel according to an embodiment of the present invention includes:

the simulation module is used for simulating the multi-ship-based helicopter by utilizing a real-time rendering technology;

the adjusting module is used for adjusting the difficulty of the control task;

and the acquisition module is used for acquiring and displaying physiological data of a trainer.

As an alternative implementation of the embodiment of the present invention, the simulation is performed by using a real-time rendering technique in the following manner: simulating a marine scene, simulating a ship-based helicopter and simulating a plurality of ships; wherein:

simulating the ocean scene includes:

using a loader to manufacture ocean effects;

simulating sea level fluctuation, foam system and helicopter offshore ripple based on a fast Fourier transform method;

adjusting a loader language parameter and changing the sea surface effect;

simulating the carrier-based helicopter includes:

based on the Unity physical system and the animation system, a helicopter flight script is manufactured and controlled;

under a fixed mode, controlling the helicopter to complete a flight task and act and recording the Transform information; storing the task action as an resolver file, and reproducing the task action by combining the resolver file with a helicopter model;

under the free mode, based on the operation script, a VR control helicopter script is manufactured, and the VR handle is combined for control;

simulating the multi-vessel comprises: based on 3Dmax, manufacturing a simulated ship model; and (3) manufacturing a preliminary model, displaying UV according to the performance and the number of the reduced surfaces, mapping, and baking by using a Unity rendering pipeline to finish the multi-ship simulation.

As an alternative to the embodiments of the present invention, task difficulties include difficult, simple and free modes; the adjusting module adjusts the difficulty of the control task in the following way: adjusting the difficulty parameter adjusts the task difficulty.

As an optional implementation manner of the embodiment of the present invention, the acquisition module acquires and displays physiological data of the trainer by the following manner: adjusting the task speed; executing a task and a task action; the physiological sensor is used for collecting physiological data in the task executing process of the trainer; the physiological data of the trainer in the training process are displayed in real time.

As an optional implementation manner of the embodiment of the present invention, the physiological data testing display device of the virtual reality combined with the control panel provided by the embodiment of the present invention further includes: a storage module; the storage module is used for constructing a database, and storing physiological data of a trainer into the database to form a training data set when task simulation is performed each time.

Therefore, the virtual reality combined with the physiological data testing display device of the control panel can adjust task difficulty, simulate and display the world in a VR mode to stimulate physiological sense organs, and automatically store physiological sense organ data. The invention builds a helicopter simulator system by accessing peripheral physiological monitoring equipment data based on a computer virtual reality technology, provides a repeatedly operated software platform for a pilot, performs multi-task and multi-parameter task simulation in the platform, collects physiological and psychological data generated by the pilot under different scenes and task situations, and calculates the collected data to form the data capable of being ground.

The foregoing is merely exemplary of the present application and is not intended to limit the present application. Various modifications and changes may be made to the present application by those skilled in the art. Any modifications, equivalent substitutions, improvements, etc. which are within the spirit and principles of the present application are intended to be included within the scope of the claims of the present application.

Claims (10)

1. A physiological data test display method combining virtual reality with a control panel is characterized by comprising the following steps:

performing multi-ship-based helicopter simulation by using a real-time rendering technology;

adjusting the difficulty of a control task;

and collecting and displaying the physiological data of the trainee.

2. The method of claim 1, wherein performing multi-vessel shipboard helicopter simulation using real-time rendering techniques comprises: simulating a marine scene, simulating a ship-based helicopter and simulating a plurality of ships; wherein:

the simulating of the ocean scene comprises:

using a loader to manufacture ocean effects;

simulating sea level fluctuation, foam system and helicopter offshore ripple based on a fast Fourier transform method;

adjusting a loader language parameter and changing the sea surface effect;

the simulating of the ship-based helicopter comprises the following steps:

based on the Unity physical system and the animation system, a helicopter flight script is manufactured and controlled;

under a fixed mode, controlling the helicopter to complete a flight task and act and recording the Transform information; storing the task action as an resolver file, and reproducing the task action by combining the resolver file with a helicopter model;

under the free mode, based on the operation script, a VR control helicopter script is manufactured, and the VR handle is combined for control;

the simulating the multi-ship comprises the following steps: based on 3Dmax, manufacturing a simulated ship model; and (3) manufacturing a preliminary model, displaying UV according to the performance and the number of the reduced surfaces, mapping, and baking by using a Unity rendering pipeline to finish the multi-ship simulation.

3. The method of claim 1, wherein the task difficulty comprises a difficult mode, a simple mode, and a free mode;

the adjusting and controlling task difficulty comprises the following steps:

adjusting the difficulty parameter adjusts the task difficulty.

4. The method of claim 1, wherein the collecting and displaying of the physiological data of the trainer comprises:

adjusting the task speed;

executing a task and a task action;

the physiological sensor is used for collecting physiological data in the task executing process of the trainer;

the physiological data of the trainer in the training process are displayed in real time.

5. The method as recited in claim 4, further comprising:

and constructing a database, and storing physiological data of a trainer into the database to form a training data set when task simulation is performed each time.

6. A virtual reality combines physiological data test display device of control panel, characterized in that includes:

the simulation module is used for simulating the multi-ship-based helicopter by utilizing a real-time rendering technology;

the adjusting module is used for adjusting the difficulty of the control task;

and the acquisition module is used for acquiring and displaying physiological data of a trainer.

7. The apparatus of claim 6, wherein the simulation is performed by a multi-vessel shipboard helicopter using real-time rendering techniques by: simulating a marine scene, simulating a ship-based helicopter and simulating a plurality of ships; wherein:

the simulating of the ocean scene comprises:

using a loader to manufacture ocean effects;

simulating sea level fluctuation, foam system and helicopter offshore ripple based on a fast Fourier transform method;

adjusting a loader language parameter and changing the sea surface effect;

the simulating of the ship-based helicopter comprises the following steps:

based on the Unity physical system and the animation system, a helicopter flight script is manufactured and controlled;

under a fixed mode, controlling the helicopter to complete a flight task and act and recording the Transform information; storing the task action as an resolver file, and reproducing the task action by combining the resolver file with a helicopter model;

under the free mode, based on the operation script, a VR control helicopter script is manufactured, and the VR handle is combined for control;

the simulating the multi-ship comprises the following steps: based on 3Dmax, manufacturing a simulated ship model; and (3) manufacturing a preliminary model, displaying UV according to the performance and the number of the reduced surfaces, mapping, and baking by using a Unity rendering pipeline to finish the multi-ship simulation.

8. The apparatus of claim 6, wherein the task difficulty comprises a difficult mode, a simple mode, and a free mode;

the adjusting module adjusts the difficulty of the control task in the following way:

adjusting the difficulty parameter adjusts the task difficulty.

9. The apparatus of claim 6, wherein the acquisition module acquires and displays the physiological data of the trainer by:

adjusting the task speed;

executing a task and a task action;

the physiological sensor is used for collecting physiological data in the task executing process of the trainer;

the physiological data of the trainer in the training process are displayed in real time.

10. The apparatus as recited in claim 9, further comprising: a storage module;

the storage module is used for constructing a database, and storing physiological data of a trainer into the database to form a training data set when task simulation is carried out each time.