CN117877343A - Parachute simulated training information processing system and parachute simulated training system - Google Patents
Parachute simulated training information processing system and parachute simulated training system Download PDFInfo
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- G06F3/01—Input arrangements or combined input and output arrangements for interaction between user and computer
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Abstract
The utility model relates to an parachuting simulation training information processing system and a parachuting simulation training system, which comprises a VR terminal and a bracelet worn by a user, wherein the VR terminal and the bracelet are respectively connected to gateway equipment through a wireless local area network, the bracelet is in wireless communication with the gateway equipment through the wireless local area network to send collected heart rate data of the user to a server, and the VR terminal carries out video stream interaction with the server through the gateway equipment; when the VR terminal fails in transmitting the video stream, transmitting transmission control information of the video stream to gateway equipment through a bracelet; the gateway equipment receives and transmits transmission control information through the bracelet, and controls a communication link for transmitting the video stream according to the transmission control information, so that the communication link operates in a normal working state. According to the technical scheme, the redundancy effect on the control information of the VR terminal is achieved by utilizing the bracelet, and the video transmission link between the VR terminal and the gateway equipment is recovered, so that the communication stability of the system is improved, and the influence of faults on the system is reduced.
Description
The application is a divisional application with the application number of 202310650049.0 and the application date of 2023-06-02, and the invention is named as an umbrella simulated training information processing system and an umbrella simulated training system.
Technical Field
The application relates to the technical field of parachuting simulation, in particular to a parachuting simulation training information processing system and a parachuting simulation training system.
Background
In parachuting training, repeated training of a learner is required by using an parachuting simulation training information processing system so that the learner can master various skills; the common parachuting simulation training information processing system is built in the environment close to an actual battlefield environment and a training environment, and various facilities are complete and functions are complete; the parachute simulated training information processing system can effectively shorten the training period, reduce the training cost, improve the training benefit and promote the rapid generation of the combat force of the troops.
With the continuous development of science, the novel parachuting simulation training information processing system is increasingly applied to new scientific technologies, for example, VR terminal equipment and a bracelet are introduced into the parachuting simulation training information processing system, the VR equipment can provide immersive experience for new parachuting students, different air conditions are perceived, risk coefficients in an actual parachuting can be reduced, a realistic parachuting environment is constructed by utilizing technologies such as space positioning, virtual simulation and data collection, heart rate data of the students can be monitored in real time, and accordingly physiological states of the students can be comprehensively monitored.
Currently, in the parachuting training process, VR terminal equipment worn by a learner is connected with a PC host, and video streams (streaming) are acquired from the PC host for use by the VR terminal of the learner. VR terminal equipment and PC host computer can be connected through wired or wireless mode, when adopting wireless mode to connect, although can break away from the constraint of cable, wireless VR uses transmission speed too slow at present, is difficult to realize high-speed data transmission, produces the problem such as transmission jam or fall the line easily to lead to the VR terminal to appear the phenomenon such as card, seriously influenced the parachuting simulation training effect.
Disclosure of Invention
Aiming at one of the technical defects, the application provides an parachuting simulation training information processing system and an parachuting simulation training system, so that the influence of transmission congestion or disconnection is reduced, and the communication stability of the system is improved.
An parachuting simulation training information processing system, comprising: the parachuting simulation training platform comprises a VR terminal and a bracelet worn by a user, gateway equipment and a server; wherein,
the VR terminal and the bracelet worn by the user perform parachuting training on the simulated training platform; the VR terminal and the bracelet are respectively connected to the gateway equipment through a wireless local area network, and the gateway equipment is connected to a server; the VR terminal is connected with the bracelet in a wireless mode;
The VR terminal performs wireless communication with gateway equipment through a wireless local area network;
the bracelet is in wireless communication with the gateway equipment through a wireless local area network, and the acquired heart rate data of the user are sent to the server; and forwarding transmission control information of the video stream transmitted between the VR terminal and the gateway device when the video stream output fails;
and the VR terminal performs video stream interaction with the server through the gateway equipment, forwards transmission control information through the bracelet, and controls a communication link for transmitting the video stream according to the transmission control information, so that the communication link operates in a normal working state.
In one embodiment, the gateway device sends a video stream to the VR terminal according to a set transmission frame rate, and the VR terminal receives the video stream at the set transmission frame rate;
the VR terminal detects a real-time receiving frame rate of a video stream received from a communication link, judges that the communication link is congested when the real-time receiving frame rate is lower than a set frame rate threshold, and judges that the communication link is disconnected when the real-time receiving frame rate is equal to 0;
the VR terminal sends a notification message of congestion or disconnection of the communication link to gateway equipment in real time through a bracelet;
And the gateway equipment performs transmission control on the communication link according to the notification message until the normal working state is restored.
In one embodiment, when the communication link is congested, the VR terminal sends a first notification message to a gateway device in real time through a bracelet; the first notification message comprises a first real-time receiving frame rate of the VR terminal and a latest first receiving video frame number;
the gateway equipment carries out frame loss processing on the video stream according to a first frame loss proportion; and calculating a second delay of the transmission of the communication link after the frame loss processing according to the set transmission frame rate, the first frame loss ratio, the first delay for forwarding the first notification message, the first received video frame number and the sent video frame number, and stopping the frame loss processing and recovering the set transmission frame rate for transmission when the first real-time received frame rate is higher than a set frame rate threshold and the second delay sum is smaller than or equal to a set time threshold.
In one embodiment, the second delay τ 2 The calculation formula of (2) is as follows:
the recovery setting transmission frame rate satisfies the following conditions:
τ 2 ≤t 0
p 1 ≥p 0
wherein P is the set transmission frame rate, a is the first frame loss ratio, m is the first received video frame number, n is the transmitted video frame number, τ 1 Is a first delay, t 0 To set the time threshold τ 2 For a second time delay, p 1 For a first real-time received frame rate, p 0 To set a frame rate threshold.
In one embodiment, when the communication link is broken, the VR terminal sends a second notification message to the gateway device through a bracelet; the second notification message comprises a disconnection flag of a communication link and a first number k of a second received video frame finally received by the VR terminal;
and when the gateway equipment receives the disconnection mark, reconstructing a communication link, and starting from the k+1st frame video frame, carrying out frame loss processing on the video stream in a second frame loss proportion until the communication link is restored to the transmission frame rate for transmission.
In one embodiment, during the frame loss processing, the VR terminal sends a second real-time received frame rate to the gateway device via a second notification message;
the gateway device judges a first frame rate difference value between a second real-time receiving frame rate and a set transmission frame rate in real time, and sets the communication link as the set transmission frame rate when the first frame rate difference value is larger than or equal to a second frame rate difference value between a set frame rate threshold value and the set transmission frame rate.
In one embodiment, the gateway device obtains a third delay time for forwarding the second notification message by the bracelet, and when the second notification message is received, the gateway device correspondingly receives a second number of the video frame issued by the server and a recovery time set by the system; and calculating a second frame loss ratio according to the third delay, the second number and the recovery time, wherein the calculation formula is as follows:
wherein x is the difference of the second number minus the first number, P is the set transmission frame rate, τ 3 Is a third delay; t is t h Is the recovery time.
In one embodiment, the VR terminal is wirelessly connected to a plurality of bracelets, and the bracelets are wirelessly connected to a plurality of VR terminals; and a plurality of hand ring networks in one area form a dynamic area communication network;
the VR terminal selects forwarding bracelets in online bracelets in the regional communication network, detects signal energy values and transmission error rates of all online bracelets in the regional communication network, calculates optimal transmission paths according to the signal energy values and the transmission error rates, determines all forwarding bracelets according to the optimal transmission paths, and establishes communication channels from the VR terminal to gateway equipment;
each bracelet in the regional communication network perceives other online bracelets in a mode of broadcasting and sending heartbeat data; the notification message carries the identity mark information of the sent VR terminal, and the bracelet forwards the notification message according to the identity mark information.
In one embodiment, the bracelet periodically transmits its own positioning information to the gateway device; the positioning information comprises an ID number of a bracelet and satellite positioning data thereof;
the gateway equipment acquires the relative spatial positions of each bracelet in the parachuting training field according to the positioning information; dividing the region according to the relative space position, and networking a plurality of hand rings belonging to one region to form a dynamic region communication network; sending networking notification messages in each regional communication network to corresponding handrings;
and the bracelet determines the affiliated regional communication network according to the received networking notification message.
An parachuting simulation training system, comprising: the parachuting simulation training platform and the parachuting simulation training information processing system; and the VR terminal and the bracelet worn by the user perform parachuting training on the simulated training platform.
The parachuting simulation training information processing system and the parachuting simulation training system comprise VR terminals and a bracelet, wherein the VR terminals and the bracelet are worn by a user and are respectively connected to gateway equipment through a wireless local area network, the bracelet is in wireless communication with the gateway equipment through the wireless local area network to send collected heart rate data of the user to a server, and the VR terminals interact with the server through the gateway equipment in a video stream manner; meanwhile, when the VR terminal fails in a communication link for transmitting the video stream, transmitting transmission control information of the video stream to gateway equipment through a bracelet; the gateway equipment receives and transmits transmission control information through the bracelet, and controls a communication link for transmitting the video stream according to the transmission control information, so that the communication link operates in a normal working state. According to the technical scheme, the bracelet is utilized to achieve the redundancy effect on the control information of the VR terminal, when the video streaming of the VR terminal fails, the video transmission link between the VR terminal and the gateway device is recovered through the communication link of the bracelet, so that the communication stability of the system is improved, and the influence of the failure on the system is reduced.
Further, when the communication link is broken, the VR terminal sends a second notification message to the gateway device through the bracelet, and the gateway device reestablishes the communication link and performs frame loss processing according to the calculated second frame loss ratio until the communication link is restored to the transmission frame rate for transmission; therefore, when the VR terminal sends the disconnection, the communication link can be rebuilt and transmitted in time, the influence of transmission interruption caused by the disconnection of the communication link is avoided, and the robustness of the system is improved.
Further, when the communication link is congested, the VR terminal sends a first notification message to the gateway device through the bracelet, the gateway device performs frame loss processing on the video stream according to a first frame loss ratio, stops frame loss processing when the video stream is restored to a proper frame rate and time delay, and finally restores to set transmission frame rate for transmission; the method can perform self-adaptive recovery on the communication link in time when the VR terminal transmits congestion, reduces adverse effects when the communication link is congested, and improves system stability.
Further, a plurality of hand rings in one area are networked to form a dynamic area communication network, forwarding hand rings can be selected from online hand rings in the area communication network, and an optimal transmission path is selected to establish a communication channel from the VR terminal to the gateway device; therefore, data can be transmitted through the optimal transmission path, all the handrings are always in the optimal networking, the system communication efficiency is improved, and the communication stability is ensured.
Additional aspects and advantages of the application will be set forth in part in the description which follows, and in part will be obvious from the description, or may be learned by practice of the application.
Drawings
The foregoing and/or additional aspects and advantages of the present application will become apparent and readily appreciated from the following description of the embodiments, taken in conjunction with the accompanying drawings, in which:
FIG. 1 is a schematic diagram of an exemplary parachuting simulation training information handling system;
FIG. 2 is a schematic diagram of an embodiment of a parachuting simulation training information handling system;
FIG. 3 is a schematic diagram of an example congestion recovery;
FIG. 4 is an exemplary schematic diagram of an open circuit reconstruction;
FIG. 5 is a networking schematic of an exemplary regional communication network;
FIG. 6 is a schematic diagram of an exemplary networking notification message structure
FIG. 7 is a schematic diagram of an exemplary transmission path;
FIG. 8 is a schematic diagram of an exemplary backup transmission scheme;
FIG. 9 is a schematic diagram of another exemplary backup transmission scheme;
FIG. 10 is a data communication system of an parachuting simulation training information handling system of an embodiment.
Detailed Description
Embodiments of the present application are described in detail below, examples of which are illustrated in the accompanying drawings, wherein the same or similar reference numerals refer to the same or similar elements or elements having the same or similar functions throughout. The embodiments described below by referring to the drawings are exemplary only for the purpose of illustrating the present application and are not to be construed as limiting the present application.
As used herein, the singular forms "a", "an", "the" and "the" are intended to include the plural forms as well, unless expressly stated otherwise, as understood by those skilled in the art. It will be further understood that the terms "comprises" and/or "comprising," when used in this specification, specify the presence of stated features, integers, steps, operations, but do not preclude the presence or addition of one or more other features, integers, steps, operations.
Referring to fig. 1, fig. 1 is a schematic structural diagram of an exemplary parachuting simulation training information processing system, in a parachuting training scene, a learner wears a VR terminal and a bracelet when performing parachuting training, the VR terminal and the bracelet communicate with a gateway device through a local area network, the gateway device communicates with a server in data, the server transmits video streams to the gateway device to transmit to each VR terminal, and meanwhile, the bracelet collects heart rate data of the learner, transmits the heart rate data to the gateway device, and transmits the heart rate data back to the server for unified monitoring and analysis, and the VR terminal can be conveniently applied due to VR wireless transmission technology; but the condition of transmission congestion or disconnection is easy to generate, and the condition that the ring is used for collecting heart rate data in parachuting simulation training is considered; therefore, the VR terminal used for the parachuting simulation training is improved, the working mode of the bracelet is also improved, the problem of transmission congestion or disconnection is solved by utilizing the bracelet to assist the VR terminal, the influence of the transmission congestion or disconnection is reduced to a certain extent, and the stability of the system is improved, so that the parachuting simulation training information processing system and the parachuting simulation training system are provided.
As shown in FIG. 2, FIG. 2 is a schematic diagram of an embodiment of a parachuting simulation training information handling system, the system comprising: the parachuting simulation training platform comprises a VR terminal and a bracelet worn by a user, gateway equipment and a server; the VR terminal and the bracelet worn by the user perform parachuting training on the simulated training platform; the VR terminal and the bracelet are respectively connected to the gateway equipment through a wireless local area network, and the gateway equipment is connected to a server; the VR terminal is connected with the bracelet in a wireless mode, and plug-ins can be respectively implanted on the VR terminal and the bracelet to realize a communication interaction function; and the VR terminal performs wireless communication with the gateway device through a wireless local area network.
The bracelet is in wireless communication with the gateway equipment through a wireless local area network, and the acquired heart rate data of the user are sent to the server; and forwarding transmission control information of the video stream transmitted between the VR terminal and the gateway device when the video stream output fails.
And the VR terminal performs video stream interaction with the server through the gateway equipment, forwards transmission control information through the bracelet, and controls a communication link for transmitting the video stream according to the transmission control information, so that the communication link operates in a normal working state.
According to the technical scheme, when the VR terminal fails in transmitting the video stream, the transmission control information of the video stream is forwarded to the gateway device through the bracelet; the gateway equipment receives and transmits transmission control information through the bracelet, and controls a communication link for transmitting the video stream according to the transmission control information, so that the communication link operates in a normal working state. According to the method and the device, the redundant effect of the control information of the VR terminal is achieved through the bracelet, when the video streaming of the VR terminal fails, the video transmission link between the VR terminal and the gateway device is recovered through the communication link of the bracelet, so that the communication stability of the system is improved, and the influence of the failure on the system is reduced.
In one embodiment, the present application provides a fault diagnosis scheme for congestion or disconnection based on a transmission frame rate for the case where congestion or disconnection is likely to occur in a communication link transmitting a video stream between a currently-present VR terminal and a gateway device.
In one embodiment, the gateway device sends a video stream to the VR terminal according to a set transmission frame rate P, and the VR terminal receives the video stream at the set transmission frame rate P; the VR terminal detects real-time access to video streams received from a communication link A frame rate, when the real-time received frame rate is lower than a set frame rate threshold p 0 And when the real-time receiving frame rate is equal to 0, judging that the communication link is blocked, and when the real-time receiving frame rate is equal to 0, judging that the communication link is broken.
In one embodiment, the fault may be further recovered according to the diagnosed congestion or open circuit in this embodiment; specifically, the VR terminal sends a notification message that congestion or disconnection occurs in the communication link to the gateway device in real time through a bracelet; and the gateway equipment performs transmission control on the communication link according to the notification message until the normal working state is restored.
According to the technical scheme of the embodiment, through judging the transmission frame rate, timely fault diagnosis is carried out on congestion or disconnection of a communication link; and when congestion or disconnection of the communication link is diagnosed, the transmission of the communication link is timely recovered, so that the system stability is ensured.
Based on the above-described diagnosed congestion or open-circuit faults, the embodiments of the present application provide a communication link recovery technical solution for congestion and open-circuit, respectively.
1. Congestion recovery:
in one embodiment, referring to fig. 3, fig. 3 is a schematic congestion recovery diagram of an example, where when congestion occurs in the communication link, the VR terminal sends a first notification message to the gateway device in real time through a bracelet; wherein the first notification message includes a first real-time received frame rate p of the VR terminal 1 And the latest first received video frame number m.
The gateway equipment performs frame loss processing on the video stream according to a first frame loss proportion a; according to the set transmission frame rate P, the first frame loss ratio a and the first delay tau for forwarding the first notification message 1 The first received video frame number m and the transmitted video frame number n calculate the second delay tau of the transmission of the communication link after the frame loss processing 2 When the first real-time receiving frame rate p 1 Above a set frame rate threshold p 0 And a second time delay tau 2 Less than or equal to a set time threshold t 0 At the time, stop the frame lossAnd recovering the set transmission frame rate P for transmission.
Specifically, when congestion occurs, the gateway device may timely receive the first real-time received frame rate p through the notification message transmitted by the wristband 1 And the latest first received video frame number m, whereby the frame loss processing can be performed according to the first frame loss ratio a, by which the communication link congestion can be reduced and the communication link tends to return to the normal state; simultaneously, a second delay tau transmitted by a communication link after frame loss processing is calculated in real time 2 Setting a threshold value for the first real-time received frame rate p 1 And a second delay tau 2 And monitoring, namely stopping frame loss processing when the corresponding condition is met, so as to recover the normal transmission state.
In this embodiment, the second delay τ 2 The calculation formula of (2) can be as follows:
the recovery setting transmission frame rate P satisfies the following conditions:
τ 2 ≤t 0
p 1 ≥p 0
wherein P is the set transmission frame rate, a is the first frame loss ratio, m is the first received video frame number, n is the transmitted video frame number, τ 1 Is a first delay, t 0 To set the time threshold τ 2 For a second time delay, p 1 For a first real-time received frame rate, p 0 To set a frame rate threshold.
In the above embodiment, when congestion occurs in the communication link, the VR terminal sends a first notification message to the gateway device through the bracelet, and transmits the real-time received frame rate and the video frame number information of the VR terminal, the gateway device performs frame loss processing on the video stream according to the first frame loss ratio, and sets a corresponding time threshold and a frame rate threshold algorithm on the gateway device to judge the time delay and the real-time frame rate, so that congestion recovery processing can be adaptively performed, and frame loss processing is stopped when the congestion recovery processing is adjusted to a proper frame rate, and finally, the transmission is performed after the frame loss rate is recovered to a set transmission frame rate; therefore, when the VR terminal sends congestion, the communication link can be recovered in a self-adaptive manner in time, adverse effects of the congestion of the communication link are reduced, and system stability is improved.
2. And (5) breaking reconstruction:
in one embodiment, referring to fig. 4, fig. 4 is an exemplary schematic diagram of a circuit breaking reestablishment, where when the communication link is broken, the VR terminal sends a second notification message to the gateway device through a bracelet; the second notification message includes a disconnection flag Tage of the communication link and a second received video frame number k received last by the VR terminal.
And when the gateway equipment receives the disconnection mark, reconstructing a communication link, and starting from a k+1st video frame, carrying out frame loss processing on the video stream at a second frame loss proportion b until the communication link is restored to a transmission frame rate P for transmission.
In one embodiment, the technical solution for circuit breaking recovery may include the following: in the frame loss processing process, the VR terminal transmits a second real-time received frame rate p through a second notification message 2 And sending the message to gateway equipment.
The gateway device judges the second real-time receiving frame rate p in real time 2 A first frame difference value psi between the transmission frame rate P and the set transmission frame rate P, when the first frame difference value psi is greater than or equal to the set frame rate threshold value P 0 A second frame rate difference (i.e., ψ+.gtoreq.p) between the set transmission frame rate P 0 -P) setting said communication link to a set transmission frame rate P.
According to the technical scheme, when the communication link is broken, the VR terminal sends a first notification message to the gateway equipment through the bracelet, the gateway equipment carries out frame loss processing on the video stream according to a first frame loss proportion, stops frame loss processing when the video stream is restored to a proper frame rate and time delay, and finally restores to set transmission frame rate for transmission; the method can restore the communication link in a self-adaptive manner in time when the VR terminal sends the disconnection, thereby reducing the adverse effect of the disconnection of the communication link and improving the system stability.
In order to better ensure the buffering effect in the frame loss process, ensure that the transmission video stream can be slowly recovered to a normal state, and avoid the phenomenon of unstable video stream in the recovery process, the embodiment provides the following communication link recovery technical scheme.
In one embodiment, the gateway device obtains a third delay τ of the wristband forwarding the second notification message 3 When receiving the second notification message, the second number k+x corresponding to the video frame issued by the receiving server and the recovery time t set by the system are correspondingly received h The method comprises the steps of carrying out a first treatment on the surface of the According to the third delay tau 3 Second number k+x and recovery time t h The second frame loss ratio b is calculated, and the calculation formula is as follows:
Wherein x is the difference of the second number k+x minus the first number k, and P is the transmission frame rate, τ, of the gateway device according to the set transmission frame rate 3 For the third delay, k+x is the frame number of the server issued video frame, t h Is the recovery time.
According to the technical scheme, through constructing the second frame loss ratio calculation scheme of the quadratic relation curve, the corresponding second frame loss ratio can be calculated in real time according to the recovery time, so that a good buffering effect can be achieved in the recovery process, the phenomenon of blocking when the VR terminal receives the video stream is avoided due to the unstable state, smooth transition is ensured, and the system stability is further improved.
In order to further clarify the technical effects of the technical solutions of the present application, further embodiments are described below with reference to the drawings.
In one embodiment, the VR terminal is wirelessly connected to a plurality of bracelets, and the bracelets are wirelessly connected to a plurality of VR terminals; and a plurality of hand ring networks in one area form a dynamic area communication network; the VR terminal selects forwarding bracelets in online bracelets in the regional communication network, detects signal energy values and transmission error rates of all online bracelets in the regional communication network, calculates optimal transmission paths according to the signal energy values and the transmission error rates, determines all forwarding bracelets according to the optimal transmission paths, and establishes communication channels from the VR terminal to gateway equipment.
Each bracelet in the regional communication network perceives other online bracelets in a mode of broadcasting and sending heartbeat data; the notification message carries the identity mark information of the sent VR terminal, and the bracelet forwards the notification message according to the identity mark information.
As shown in fig. 5, fig. 5 is a networking schematic diagram of an exemplary regional communication network, where a server divides all the bracelets into a plurality of spatial areas according to spatial positions through gateway devices, and the bracelets belonging to the same spatial area are networked, and the bracelets in the regional communication network sense other bracelets by broadcasting and sending heartbeat data, where black dots in the figure represent bracelets, and where a dashed frame represents a networking area, such as being divided into "network 1", "network 2" … … "network K", so as to form a dynamic regional communication network.
In the parachuting training, the wrist rings worn by the students are distributed in a parachuting training field to form a large distribution space, therefore, the wrist rings used by the parachuting simulation training information processing system can be divided according to space areas to form space areas, each space area is networked to form a dynamic area communication network, and the wrist rings in the area communication network sense other wrist rings in a mode of broadcasting and sending heartbeat data so as to keep communication.
In one embodiment, for a dynamic regional communication network networking solution, the following may be adopted:
and each bracelet is managed to be networked through the server, and each bracelet transmits the ID number of the bracelet and satellite positioning data (such as a Beidou positioning system and a GPS positioning system) to the gateway equipment in a regular transmission mode to be forwarded to the server.
Because the positioning information only contains satellite positioning data, and in the process of parachute training, the wrist rings worn by students are distributed in a three-dimensional space, a three-dimensional coordinate system (O-xyz coordinate system) is further established by using a site model, the height is measured by using a wireless positioning technology, and the relative spatial position is obtained by combining the satellite positioning data.
The server divides the areas according to the relative space positions, networking a plurality of bracelets belonging to one area to form a dynamic area communication network, and then sending networking notification messages to corresponding bracelets in each area communication network through gateway equipment; the bracelet can determine the area communication network to which the bracelet belongs by directly receiving gateway equipment or receiving networking notification messages forwarded by other bracelets, and communicates with the bracelet in the area communication network.
According to the technical scheme, the server is used for managing the handrings, the relative spatial positions in the parachuting training field are calculated, networking is carried out according to the relative spatial positions to form a dynamic regional communication network, the spatial regions are divided according to the dynamic monitoring condition, and all the handrings are always in the optimal networking, so that the communication network can be optimized, and the communication stability is improved.
In one embodiment, the dynamic regional communication network based on the networking of the foregoing embodiment may adopt the following technical solutions when performing communication transmission with the gateway device:
when the bracelet transmits heart rate data or control information (such as a first notification message and a second notification message), the server can select the optimal receiving bracelet from the online bracelet and the gateway according to the direct communication state of the online bracelet and the gateway in each regional communication network. Specifically, when the server sends the networking notification message, the ID numbers of the bracelets in the regional communication network to which the server belongs are ordered in the networking notification message, the first ordered bracelet is the default receiving bracelet, and the subsequent bracelets can be the backup receiving bracelets.
For the format of the networking notification message, reference may be made to fig. 6, where fig. 6 is a schematic diagram of an exemplary networking notification message structure; in the figure, the server divides all the bracelets into 50 regional communication networks, wherein the network 1 comprises bracelets with ID numbers 078, 032, 081, 001, 093, 101 and the like, and can know that the bracelet 078 is a receiving bracelet according to the sequence number, the bracelet 032 is a backup forwarding node, and so on; thus, the transmitting wristband may dynamically select the optimal receiving wristband to transmit the transmission data.
In the transmitting process, the bracelet needing to transmit data generates an optimal transmission path which is routed to the receiving bracelet, converts the heart rate data of the bracelet into transmission data of a self-defined protocol and transmits the transmission data to the receiving bracelet through the optimal transmission path.
Specifically, sending an online bracelet in a bracelet detection area communication network, and acquiring signal energy values and transmission error rates of all online bracelets; establishing a plurality of transmission paths from a transmitting bracelet to a receiving bracelet according to an online bracelet, and determining the passing bracelet of each transmission path; calculating corresponding comprehensive evaluation values according to the number of the hand rings of each transmission path, the signal energy value and the transmission error rate, and selecting an optimal transmission path according to the comprehensive evaluation values; and converting the heart rate data into transmission data of a custom protocol, and forwarding the transmission data to a receiving bracelet through an optimal transmission path.
For example, for the signal energy value and the transmission error rate of the online bracelet, each bracelet in the regional communication network can periodically broadcast heartbeat data to other bracelets and receive the heartbeat data (including the ID number, the signal energy value and the transmission error rate of the bracelet) broadcast by the other bracelets; detecting an online bracelet in the regional communication network according to the received heartbeat data broadcasted by other bracelets; and determining the signal energy value and the transmission error rate of each online bracelet according to the ID number of the online bracelet.
For example, in calculating the comprehensive evaluation value of the transmission path, the following calculation formula may be employed:
α+β+γ=1
in the above formula, n is the number of the hand rings passing through the transmission path, Q represents the signal energy value of the hand rings, P represents the transmission error rate of the hand rings, M represents the comprehensive evaluation value, subscripts 1-n represent the corresponding hand ring numbers, and α, β, γ are set constants.
Preferably, α=0.3, β=0.2, γ=0.5; the value distribution can fully integrate the influence factors such as the number of the hand rings, the signal energy value, the transmission error rate and the like, and fully reflect the transmission capacity and the transmission effect of each hand ring.
For example, as shown in fig. 7, fig. 7 is a schematic diagram of an exemplary transmission path, assuming that there are three paths for transmission from the transmitting bracelet a to the receiving bracelet E:
transmission path 1: a, B and E;
transmission path 2: A-E;
transmission path 3: a, C, D and E;
in the selection of the transmission paths, the comprehensive evaluation value calculation formula is utilized to comprehensively evaluate each transmission path, and the obtained comprehensive evaluation value is sequenced as 'transmission path 1', 'transmission path 2', 'transmission path 3'; therefore, after the comprehensive evaluation, although the number of the passed hand rings is the smallest, the "transmission path 2" is smaller than the "transmission path 1" because of factors of low signal energy and high transmission error rate due to the long distance, and the "transmission path 3" selects the "transmission path 1" for data transmission because of the smallest total evaluation value obtained by the overall calculation due to the large number of the passed hand rings.
For example, when the transmission data is forwarded to the receiving bracelet through the optimal transmission path, the first transmission data can be generated according to the self first heart rate data by a custom protocol, and the first transmission data is sent to the next bracelet on the optimal transmission path in a point-to-point communication mode.
According to the scheme of the embodiment, through the heartbeat data periodically broadcast by each bracelet in the regional communication network, each bracelet can acquire the online bracelet in the regional communication network, and can acquire the signal energy value and the transmission error rate of each online bracelet, so that surrounding bracelets can be perceived in real time, the mutual communication state is maintained, and even if part of bracelets are broken, the situation can be detected in time. When data is transmitted, a plurality of transmission paths are calculated from an online bracelet, and meanwhile, a comprehensive evaluation algorithm based on the number of the bracelet, the signal energy value and the transmission error rate is designed, and the optimal transmission path is selected for transmission, so that all influencing factors of communication transmission can be fully considered, and the transmission path with optimal communication quality is used, and therefore the efficiency and stability of data transmission can be ensured.
For example, in communication between the bracelets, the flow may be as follows: firstly, a sender divides transmission data into a plurality of data packets and generates a data packet queue; sending a data transmission request (comprising the number of data packets and the data volume) to a receiver; after receiving the transmission request, the receiver sends a data transmission confirmation to the sender; after receiving the transmission confirmation, the sender reads a first data packet from the data packet queue and sends the first data packet to the sender; after receiving the first data packet, the receiving side performs over-checking on the data packet and replies confirmation to the sending side, and the steps are repeated until the data packet in the data packet queue is sent; the sender refers to a bracelet needing to send data, and the receiver refers to a bracelet needing to receive data.
After the flow is finished, the next bracelet acquires corresponding first heart rate data from the first transmission data sent by all other received bracelets according to a custom protocol, combines the first heart rate data with own second heart rate data to obtain second transmission data, and sends the second transmission data to the next bracelet on an optimal transmission path in a point-to-point communication mode; and so on until the transmission data of each sending bracelet is sent to the receiving bracelet.
In the above technical solution, the transmission data is formed based on a custom protocol, and for the custom protocol, a custom data format can be embedded based on a bluetooth protocol or a WiFi protocol, so as to form a required transmission protocol; in the transmitting process, through the sub-packet transmission and the packet-by-packet check sum confirmation protocol, when transmission interruption occurs, the standby transmission path can be timely utilized for transmitting, the data integrity can be ensured, the packet loss is avoided, and the communication stability is ensured.
For example, taking the above-mentioned "transmission path 3" as an example, that is, in the transmission process of a→c→d→e, the transmitting bracelet a first transmits the first transmission data to the second bracelet C, the second bracelet C generates the second transmission data and transmits it to the third bracelet D, and the third bracelet D generates the third transmission data and transmits it to the receiving bracelet E, thereby completing the forwarding process on the transmission path.
According to the technical scheme, when the transmission data is transmitted, the transmitting bracelet generates the transmission data by the heart rate data of the transmitting bracelet and transmits the transmission data to the next bracelet, the next bracelet receives the transmission data of at least one transmitting bracelet, and the new transmission data is formed by combining the heart rate data generated by the transmitting bracelet and then transmitted to the next bracelet, so that the heart rate data is transmitted to the receiving bracelet with optimal communication quality and is transmitted to the gateway in the step-by-step transmission mode.
In general, at least one receiving bracelet is set in an area communication network, and when a certain number of receiving bracelets are reached in the area communication network, a plurality of receiving bracelets can also be set, so that the receiving bracelets in the area communication network can always maintain an optimal communication state with a gateway, and the communication efficiency and the communication stability are ensured.
In one embodiment, in order to improve redundancy performance of the system when transmitting data, in a process that the receiving bracelet forwards the transmission data sent by each sending bracelet in the regional communication network to the gateway device, a backup transmission scheme of the transmission data may also be designed.
Accordingly, the server can select one receiving bracelet from the adjacent regional communication networks of the receiving bracelets as a backup forwarding node according to the adjacent regional communication networks of the regional communication networks; in the process that the receiving bracelet forwards the transmission data to the gateway equipment, if a communication link with the gateway equipment is broken, the transmission data to be sent is forwarded to a backup forwarding node; the backup forwarding node combines the received transmission data with the transmission data which needs to be sent by the backup forwarding node, and then sends the combined transmission data to the gateway equipment.
For example, referring to fig. 8, fig. 8 is a schematic diagram illustrating an exemplary backup transmission scheme, where when a server may add a backup area communication network to a networking notification message, as in the networking notification message structure shown in fig. 6, the backup area communication network of "network 1" may select "network 2", so that when a backup forwarding terminal needs to be used, the receiving bracelet 078 of "network 1" may select the receiving bracelet 002 of "network 2" as a backup forwarding node; the receiving bracelet 078 of the network 1 can forward the transmission data to the receiving bracelet 002 of the network 2 to the gateway device, and the transmission data is divided into a plurality of data packets, so that the data packets are transmitted from the communication link disconnection position; the receiving wristband 002 of the "network 2" combines the data to be transmitted and transmits the combined data to the gateway device.
According to the technical scheme, the backup forwarding node is arranged for the receiving bracelet, so that when a communication link is broken, transmission data can be forwarded to the gateway through the adjacent regional communication network in time, the redundancy effect is realized, and the communication stability is ensured.
In one embodiment, referring to fig. 9, fig. 9 is a schematic diagram of another exemplary backup transmission scheme, for which, when a communication link between a default receiving bracelet and a gateway is broken, a backup forwarding node is selected to receive transmission data of each bracelet in the regional communication network to which the backup forwarding node belongs; the backup forwarding node sends the transmission data to the gateway or to the next receiving bracelet.
For example, in the "network 1" shown in fig. 6, when the communication link between the bracelet 078 and the gateway is broken, the backup forwarding node 032 is selected to receive the transmission data in the regional communication network and forward to the gateway device, such as a new communication link (1) in the figure, or to the bracelet 002 and forward to the gateway device, such as a new communication link (2) in the figure.
According to the scheme of the embodiment, when the communication link of the receiving bracelet is broken, the backup receiving bracelet in the regional communication network can be started in time to send transmission data, so that the communication stability can be ensured.
An embodiment of the parachuting simulation training system is set forth below.
Referring to fig. 10, fig. 10 is a schematic structural diagram of an embodiment of a parachuting simulation training system, comprising: the parachuting simulation training platform and the parachuting simulation training information processing system; the VR terminal and the bracelet worn by the user perform parachuting training on the simulation training platform, and the gateway equipment is connected to the rear server.
As illustrated, the circles in the figure represent the hand-rings, and the "network 1", "network 2" … … "network K" within the dashed box represent one networked regional communication network, each of which transmits transmission data to the gateway device through the network of receiving nodes.
The foregoing is only a partial embodiment of the present application, and it should be noted that, for a person skilled in the art, several improvements and modifications can be made without departing from the principle of the present application, and these improvements and modifications should also be considered as the protection scope of the present application.
Claims (10)
1. An parachuting simulation training information processing system, comprising: the parachuting simulation training platform comprises a VR terminal and a bracelet worn by a user, gateway equipment and a server; wherein,
the VR terminal and the bracelet are respectively connected to the gateway equipment through a wireless local area network, and the gateway equipment is connected to a server; the VR terminal is connected with the bracelet in a wireless mode;
the bracelet is in wireless communication with the gateway equipment through a wireless local area network, and the acquired heart rate data of the user are sent to the server; the gateway equipment sends a video stream to the VR terminal according to a set transmission frame rate, the VR terminal receives the video stream at the set transmission frame rate and forwards transmission control information through the bracelet;
when the communication link is broken, the VR terminal sends a second notification message to gateway equipment through a bracelet; the second notification message comprises a disconnection flag of a communication link and a first number k of a second received video frame finally received by the VR terminal;
And when the gateway equipment receives the disconnection mark, reconstructing a communication link, and starting from the k+1st frame video frame, carrying out frame loss processing on the video stream in a second frame loss proportion until the communication link is restored to the transmission frame rate for transmission.
2. The parachuting simulation training information handling system of claim 1, wherein the VR terminal detects a real-time received frame rate of a video stream received from a communication link and determines that a disconnection of the communication link occurs when the real-time received frame rate is equal to 0.
3. The parachuting simulation training information processing system of claim 1, wherein during frame loss processing, the VR terminal sends a second real-time received frame rate to the gateway device via a second notification message;
the gateway device judges a first frame rate difference value between a second real-time receiving frame rate and a set transmission frame rate in real time, and sets the communication link as the set transmission frame rate when the first frame rate difference value is larger than or equal to a second frame rate difference value between a set frame rate threshold value and the set transmission frame rate.
4. The parachuting simulation training information processing system according to claim 3, wherein the gateway device obtains a third delay of forwarding the second notification message by the bracelet, and when the second notification message is received, the gateway device corresponds to a second number of the video frame issued by the receiving server and a recovery time set by the system; and calculating a second frame loss ratio according to the third delay, the second number and the recovery time.
5. The parachuting simulation training information processing system of claim 4, wherein the second frame loss ratio is calculated as follows:
wherein b is the second frame loss ratio, x is the second number minus the first numberThe difference of the numbers, P is the set transmission frame rate, τ 3 Is a third delay, t h Is the recovery time.
6. The parachuting simulation training information processing system of claim 1, wherein the VR terminal sends a first notification message to a gateway device in real time through a bracelet when the communication link is congested; the first notification message comprises a first real-time receiving frame rate of the VR terminal and a latest first receiving video frame number;
the gateway equipment carries out frame loss processing on the video stream according to a first frame loss proportion; calculating a second delay of the transmission of the communication link after the frame loss processing according to the set transmission frame rate, the first frame loss ratio, the first delay for forwarding the first notification message, the first received video frame number and the sent video frame number, and stopping the frame loss processing and recovering the set transmission frame rate for transmission when the first real-time received frame rate is higher than a set frame rate threshold and the second delay sum is smaller than or equal to a set time threshold;
The second time delay tau 2 The calculation formula of (2) is as follows:
the recovery setting transmission frame rate satisfies the following conditions:
τ 2 ≤t 0
p 1 ≥p 0
wherein P is the set transmission frame rate, a is the first frame loss ratio, m is the first received video frame number, n is the transmitted video frame number, τ 1 Is a first delay, t 0 To set the time threshold τ 2 For a second time delay, p 1 For a first real-time received frame rate, p 0 To set a frame rate threshold.
7. The parachuting simulation training information processing system of any one of claims 1-6, wherein the VR terminal is wirelessly connected to a plurality of hand-rings, the hand-rings being wirelessly connected to a plurality of VR terminals; and a plurality of hand ring networks in one area form a dynamic area communication network;
the VR terminal selects forwarding bracelets in online bracelets in the regional communication network, detects signal energy values and transmission error rates of all online bracelets in the regional communication network, calculates optimal transmission paths according to the signal energy values and the transmission error rates, determines all forwarding bracelets according to the optimal transmission paths, and establishes communication channels from the VR terminal to gateway equipment.
8. The parachuting simulation training information processing system of claim 7, wherein each bracelet in the regional communication network senses other online bracelets by broadcasting heartbeat data; the notification message carries the identity mark information of the sent VR terminal, and the bracelet forwards the notification message according to the identity mark information.
9. The parachuting simulation training information processing system of claim 8, wherein the bracelet periodically transmits its own positioning information to a gateway device; the positioning information comprises an ID number of a bracelet and satellite positioning data thereof;
the gateway equipment acquires the relative spatial positions of each bracelet in the parachuting training field according to the positioning information; dividing the region according to the relative space position, and networking a plurality of hand rings belonging to one region to form a dynamic region communication network; sending networking notification messages in each regional communication network to corresponding handrings;
and the bracelet determines the affiliated regional communication network according to the received networking notification message.
10. An parachuting simulation training system, comprising: a parachuting simulation training platform and parachuting simulation training information processing system according to any one of claims 1-9; and the VR terminal and the bracelet worn by the user perform parachuting training on the simulated training platform.
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