RU167769U1 - DEVICE FORMING VIRTUAL ARRIVAL OBJECTS - Google Patents

Abstract

A useful model relates to devices designed to form virtual objects of augmented reality, namely, devices for forming virtual objects of augmented reality, containing a housing containing an input module for data about the environment, a display connected to a computing module processing data. According to a utility model, the environmental data input module is designed as a sound radiation source and a reflected sound signal receiver connected to a computing module. Achievable technical result - the ability to build a three-dimensional model of the surrounding space for binding virtual objects of augmented reality in low light or in its absence, as well as to increase the accuracy of building a three-dimensional model of the surrounding space.

Description

The technical field to which the utility model relates.

The utility model relates to devices intended for the formation of virtual objects of augmented reality, namely, devices for the formation of virtual objects of augmented reality, comprising a housing in which a module for inputting data about the surrounding space, a display connected to a computing module that processes the data are located. In this paper, the following terms are used.

A virtual object is a non-existent object created by technical means, transmitted to a person (through vision, hearing, etc.), sensations from which are imitated by technical means.

Augmented reality - perceived mixed reality created using elements of perceived reality, "supplemented" by computer (when virtual objects are displayed in the field of view).

Augmented reality virtual object generation device — any computer device that has a display and an input module for surrounding data that can transmit real-time data to a computing module for analysis and display an additional virtual image. Typical representatives of this class of devices: a smartphone, a tablet computer, a computer with a headset in the form of augmented reality glasses such as Google Glass and the like.

Display - information output unit for visual presentation to the user. It can be made in the form of a liquid crystal screen, or it can simply be a surface onto which the image is projected, for example, glasses are transparent, on which only additional virtual objects of augmented reality are displayed.

Smartphone (eng. Smartphone - smart phone) - a cell phone, complemented by the functionality of a personal digital assistant.

State of the art

Currently, an increasing number of people use various electronic devices and interact with virtual objects. This happens not only in computer games, but also in the learning process, as well as, for example, in the remote trading of goods, when the buyer makes a purchase decision using the virtual model of goods. At the same time, the creation of augmented reality looks like the most promising direction of development - that is, combining on the display of a computer device or smartphone and virtual or augmented reality glasses of virtual objects together with a real image received in real time from the data input unit about the surrounding space of the specified device.

To create the effect of the presence of virtual objects of augmented reality in ordinary space, it is necessary to bind to the real objects displayed on the image transmission device to the user those same augmented reality virtual objects that are modeled in real time. To bind, you need to transfer data about the world to the computing module of the device to impact augmented reality on virtual objects.

Known devices for the formation of virtual objects of augmented reality, containing a housing in which there is a module for inputting data about the environment, a display connected to a computing module that processes the data. This level of technology is disclosed in the publication of a patent description for a utility model of the Russian Federation No. 138628 of 03/20/2014

This device is the closest in technical essence and the achieved technical result and is selected for the prototype of the proposed utility model. As well as a utility model, the prototype can display virtual objects of augmented reality on the display. The module for entering data about the environment is made in the form of a video camera.

The disadvantage of this prototype is the inability to build a three-dimensional model of the surrounding space in low light or in its absence. In addition, even in the presence of lighting, image analysis algorithms from a video camera give a low accuracy in estimating the distance to objects (that is, an exact solution to the problem of constructing a 3D model from a video camera).

Utility Model Disclosure

This utility model mainly aims to propose a device for generating virtual objects of augmented reality, comprising a housing in which a module for inputting data about the surrounding space is located, a display connected to a computing module that processes the data, which allows at least smoothing, at least , one of the above disadvantages, namely, to provide the ability to build a three-dimensional model of the surrounding space for binding virtual objects of augmented reality with a weak sveschenii or in its absence, as well as improve the accuracy of a three-dimensional model of the surroundings, which is the technical problem.

To achieve this goal, the module for inputting data about the environment is made in the form of a source of sound radiation, and a receiver of the reflected sound signal connected to the computing module. Thanks to these advantageous characteristics, it is possible to emit a special signal, by measuring the travel time of which the receiver can judge the exact distance to the object from which it was reflected, and thus it becomes possible to build an accurate three-dimensional model of the surrounding space for the exact placement of virtual objects of augmented reality in it .

There is a variant of the utility model in which the device comprises a control module connected to the computing module, configured to display a signal on the device to indicate the need to change the position of the device in space. Thanks to this advantageous feature, it becomes possible to automatically obtain visual information about the need to change the position of the device in space.

There is also a variant of the utility model in which the control module is configured to transmit voice messages to the user to give the device the necessary orientation in space. Thanks to this advantageous feature, it becomes possible to automatically receive voice information that it is necessary to change the position of the device in space.

There is also such a variant of the utility model in which the computing module has a data sufficiency checker for constructing a three-dimensional model of the surrounding space from the information received from the receiver of the reflected signal. Thanks to this advantageous characteristic, it becomes possible to automatically receive information that the scanning process of the surrounding space should be continued.

There is also a variant of the utility model in which the sound radiation source is configured to emit a sound signal in the range of 40-45 kHz. Thanks to these advantageous characteristics, it is possible to use precisely the ultrasonic range for emitting an audio signal in order to increase the accuracy of distance calculation and to exclude the sound effect of the device on people and animals.

There is another embodiment of a utility model in which a computing module is connected to a unit for determining the position of the device relative to cardinal points. Thanks to these advantageous characteristics, it becomes possible to automatically tie the position of the device to the cardinal points to simplify the construction of a three-dimensional model of the surrounding space.

Brief Description of the Drawings

Other distinguishing features and advantages of this utility model clearly follow from the description below for illustration and not being restrictive, with reference to the accompanying drawings, in which:

- figure 1 depicts a diagram of a device for forming virtual objects of augmented reality according to a utility model,

- figure 2 schematically depicts the steps of the method of forming virtual objects of augmented reality according to a utility model.

According to figure 1, the device for forming virtual objects of augmented reality contains a housing 1, in which there is a module for inputting data about the surrounding space 2, a display 3, connected to a computing module 4 that processes the data. The input module about the surrounding space 2 is made in the form of a source of sound radiation 5 connected to the computing module 4, and a receiver 6 of the reflected sound signal connected to the computing module 4.

The device optionally contains a control module 7 connected to the computing module 4, configured to display a signal on the device 3 about the need to change the position of the device in space.

The control module 7 may be configured to transmit voice messages to the user to give the device the necessary orientation in space. To do this, he sends voice messages to the speaker 8 of the device.

Computing module 4 may have a block 41, a data sufficiency check block for constructing a three-dimensional model of the surrounding space from the information received from the receiver 6 of the reflected signal.

The sound radiation source 5 may be configured to emit a sound signal in the range of 40-45 kHz.

The computing module 4 can be connected to the unit 9 for determining the position of the device relative to the cardinal points, that is, a compass.

The signal reflecting the object is conventionally depicted in figure 1 as 10.

Utility Model Implementation

The device for forming virtual objects of augmented reality works as follows. We give the most comprehensive example of the implementation of the utility model, bearing in mind that this example does not limit the use of the utility model.

According to figure 2:

Stage A1. Using the source 5 of the sound signal emit a sound signal, mainly in the ultrasonic range of 40-45 kHz.

Stage A2. Since the beam of the source 5 of the sound signal is quite narrow, to scan a significant amount of space and build its three-dimensional model, it is necessary to scan the space, the device using the control module 7 instructs the user 9 visually through the display 3 or by voice through the speaker 8) to gradually turn the device into horizontal plane. In this case, the device may lie on an arbitrary horizontal surface.

Stage A3. Rotate the device discretely, with a given angular pitch, or continuously.

Stage A4. If an invalid signal was received at the current scan iteration by the reflected ultrasound receiver (for example, the space between the sound source 5 and the object was accidentally blocked, for example, by the user's hand), this fact is detected by the change in the distance to the object during the scan (the signal from the receiver fluctuates ) The control module 7 can give instructions to the user by displaying an angular marking with an arrow (similar to a compass card) and / or giving voice prompts on the orientation of the device. The angle of rotation of the device is determined by the built-in compass 9.

Stage A5. Create a three-dimensional model of the surrounding space.

Stage A6. They create virtual objects of augmented reality, tie them to the created three-dimensional model of the surrounding space and display it on the display of 3 devices.

The sequence of steps is approximate and allows you to rearrange, reduce, add or perform some operations at the same time without losing the ability to provide the formation of virtual objects of augmented reality.

Industrial applicability

The proposed device for the formation of virtual objects of augmented reality can be implemented by a specialist in practice and, when implemented, ensures the implementation of the declared purpose, which allows us to conclude that the criterion of "industrial applicability" for the invention is met.

In accordance with the proposed utility model made a prototype device. Tests of the prototype showed that it provides the ability to:

- radiation of a sound signal,

- receiving a reflected sound signal,

- calculating the distance to objects,

- checking the sufficiency of information about the environment,

- automatically indicate to the user a change in the position of the device,

- automatic construction of a three-dimensional model of the surrounding space,

- automatically linking virtual objects of augmented reality to the created three-dimensional model of the surrounding space and displaying them on the display of the device.

Thus, in this utility model, the task is achieved - the ability to build a three-dimensional model of the surrounding space for binding virtual objects of augmented reality in low light or in its absence, as well as to increase the accuracy of building a three-dimensional model of the surrounding space.

Indeed, this useful model allows you to build virtual scenes with reference to a precisely calculated three-dimensional model of real surrounding space, and due to the fact that the construction of a three-dimensional model is based on ultrasound echolocation, the process of linking virtual objects of augmented reality to a three-dimensional model of surrounding space can be performed as if poor lighting, and in its complete absence.

Claims (6)

1. The device for generating virtual objects of augmented reality, comprising a housing in which the module for inputting data about the surrounding space, a display connected to a computing module processing the data, wherein the module for inputting data about the surrounding space is made in the form of a source of sound radiation, and a receiver of the reflected sound signal connected to the computing module.
2. The device according to claim 1, characterized in that the device comprises a control module connected to the computing module, configured to display a signal on the device display about the need to change the position of the device in space.
3. The device according to p. 2, characterized in that the control module is configured to transmit voice messages to the user about giving the device the necessary orientation in space.
4. The device according to claim 1, characterized in that the computing module has a data sufficiency checker for constructing a three-dimensional model of the surrounding space from the information received from the reflected signal receiver.
5. The device according to claim 1, characterized in that the source of sound radiation is configured to emit a sound signal in the range of 40-45 kHz.
6. The device according to claim 1, characterized in that the computing module is connected to a unit for determining the position of the device relative to the cardinal points.

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