CN107610044A

CN107610044A - Image processing method, computer-readable recording medium and virtual reality helmet

Info

Publication number: CN107610044A
Application number: CN201710758206.4A
Authority: CN
Inventors: 王明
Original assignee: Goertek Techology Co Ltd
Current assignee: Goertek Optical Technology Co Ltd
Priority date: 2017-08-29
Filing date: 2017-08-29
Publication date: 2018-01-19

Abstract

The invention discloses a kind of image processing method, computer-readable recording medium and virtual reality helmet, this method to include：Obtain image to be displayed corresponding to first angle of visual field, virtual reality helmet optical component second angle of visual field and second angle of visual field corresponding to, the second field range size on the screen of the virtual reality helmet；Using first angle of visual field, second angle of visual field and the second field range size, it is calculated corresponding to first angle of visual field, the first field range size on the screen of the virtual reality helmet；Using the first field range size, the size of the image to be displayed is calculated；According to the size of the image to be displayed, optic aberrance revising processing is carried out to the image to be displayed.According to one embodiment of present invention, the experience of user is improved.

Description

Image processing method, computer-readable recording medium and virtual reality helmet

Technical field

The present invention relates to technical field of virtual reality, more particularly, to a kind of image processing method, computer-readable deposit Storage media and virtual reality helmet.

Background technology

Virtual reality device is equipped with optical lens.Optical lens has specific FOV (Field of View, visual field Angle), in conjunction with the structure design of virtual reality device, determine user by the optical lens virtual reality device screen On field range.Fig. 1 shows the field range on the screen for the virtual reality device that user is watched by optical lens Schematic diagram.

In order to improve the authenticity of Consumer's Experience, when developing VR (Virtual Reality, virtual reality) applications, meeting VR scenes are designed according to the FOV of optical lens, so that in the viewing area of the screen of VR equipment and the visual field of optical lens Scope is coincide, and distortion chromatic aberration correction is combined when adjusting viewing area, ensure that VR scenes and the uniformity of optical lens.

When the optical lens of FOV and the VR equipment of the picture of input to VR equipment is inconsistent, user will be had a strong impact on Experience.Such as the external camera of VR equipment, it is necessary to camera picture is inputted to VR equipment to be shown, without Possess different FOV with camera, and cannot ensure it is consistent with the FOV of the optical lens of VR equipment, now, if by camera's Content is shown to will result within sweep of the eye for lens and is not inconsistent by the content of lens inspection and the FOV of lens, influences Experience.

Accordingly, it is desirable to provide a kind of new technical scheme, is improved for above-mentioned technical problem of the prior art.

The content of the invention

It is an object of the present invention to provide a kind of new solution of image processing method.

According to the first aspect of the invention, there is provided a kind of image processing method, including：

Obtain image to be displayed corresponding to first angle of visual field, virtual reality helmet optical component second angle of visual field With second angle of visual field corresponding to, the second field range size on the screen of the virtual reality helmet；

Using first angle of visual field, second angle of visual field and the second field range size, it is calculated described First angle of visual field is corresponding, the first field range size on the screen of the virtual reality helmet；

Using the first field range size, the size of the image to be displayed is calculated；

According to the size of the image to be displayed, optic aberrance revising processing is carried out to the image to be displayed.

Alternatively, first angle of visual field corresponding to the image to be displayed is the external equipment of the virtual reality helmet Optical component the angle of visual field.

Alternatively, first angle of visual field corresponding to image to be displayed is obtained, including：In the virtual reality helmet and institute When stating external equipment foundation connection, the virtual reality helmet obtains the device parameter of the external equipment, wherein, it is described Device parameter includes the angle of visual field of the optical component of the external equipment.

Alternatively, using first angle of visual field, second angle of visual field and the second field range size, calculate To the first field range size corresponding to first angle of visual field, on the screen of the virtual reality helmet, including：

The first field range size is calculated based on following calculating formula,

R=R* [tan (FOV₁/2)/tan(FOV₂/ 2)], wherein, r is zone radius corresponding to first field range Size, R are zone radius size, FOV corresponding to second field range₁For first angle of visual field, FOV₂For described second The angle of visual field.

Alternatively, using the first field range size, the size of the image to be displayed is calculated, including：

The size of the image to be displayed is calculated based on following calculating formula,

R=K₀+K₁*h+K₂*h²+K₃*h³+…+K_n*hⁿ, wherein, h is square area corresponding to the image to be displayed The length of side, r are zone radius size, K corresponding to first field range₀、K₁、K₂、K₃、……K_nWorn for the virtual reality Coefficient corresponding to the optical component of equipment.

Alternatively, according to the size of the image to be displayed, optic aberrance revising processing is carried out to the image to be displayed, Including：

Multiple characteristic points are determined from the image to be displayed, according to the size of the image to be displayed, determine each feature Distance of the point to the central point of the image to be displayed；

Optic aberrance revising processing is carried out to the image to be displayed based on following calculating formula,

L'=K₀+K₁*l+K₂*l²+K₃*l³+…+K_n*lⁿ, wherein, l is characterized the central point for a little arriving the image to be displayed Distance, K₀、K₁、K₂、K₃、……K_nFor coefficient corresponding to the optical component of the virtual reality helmet, l ' is the spy Sign point arrives the distance of the central point of the image to be displayed after optic aberrance revising is handled.

Alternatively, methods described also includes：

Image to be displayed after optic aberrance revising is handled is shown on the screen of the virtual reality helmet Show.

Alternatively, the image to be displayed after optic aberrance revising is handled is on the screen of the virtual reality helmet After being shown, in the case where first angle of visual field is less than second angle of visual field, user passes through the virtual reality The region of image to be displayed after the optic aberrance revising processing that the optical component of helmet is watched is described first The angle of visual field is corresponding, the first field range size on the screen of the virtual reality helmet；

In the case where first angle of visual field is more than second angle of visual field, user is worn by the virtual reality and set The region of image to be displayed after the optic aberrance revising processing that standby optical component is watched is second angle of visual field Second field range size corresponding, on the screen of the virtual reality helmet；

In the case where first angle of visual field is equal to second angle of visual field, user is worn by the virtual reality and set The region of image to be displayed after the optic aberrance revising processing that standby optical component is watched is second angle of visual field Second field range size corresponding, on the screen of the virtual reality helmet.

According to the second aspect of the invention, there is provided a kind of computer-readable recording medium, the computer-readable storage Media storage has a computer program, and the computer program is by one or more computing device to realize any of the above-described institute The image processing method stated.

According to the third aspect of the invention we, there is provided a kind of virtual reality helmet, including：Memory, processor and It is stored in the computer program that can be run on the memory and on the processor, computer described in the computing device The image processing method described in any one as described above is realized during program.

Image processing method, computer-readable recording medium and virtual reality helmet provided by the invention, pass through profit Corresponding to image to be displayed first angle of visual field, virtual reality helmet optical component second angle of visual field and the second visual field Corresponding to angle, the second field range size on the screen of virtual reality helmet, obtain corresponding to first angle of visual field, The first field range size on the screen of virtual reality helmet, then, using the first field range size, it is calculated The size of image to be displayed, finally, according to the size of image to be displayed, optic aberrance revising processing is carried out to image to be displayed, So that the scene of image to be displayed transmission matches with second angle of visual field, the authenticity of experience is improved.

By referring to the drawings to the present invention exemplary embodiment detailed description, further feature of the invention and its Advantage will be made apparent from.

Brief description of the drawings

It is combined in the description and the accompanying drawing of a part for constitution instruction shows embodiments of the invention, and even It is used for the principle for explaining the present invention together with its explanation.

Fig. 1 shows the signal of the field range on the screen for the virtual reality device that user is watched by optical lens Figure.

Fig. 2 shows the process chart of image processing method according to an embodiment of the invention.

Fig. 3 shows the schematic diagram of optic aberrance revising process according to an embodiment of the invention.

Fig. 4 shows viewing area corresponding to first angle of visual field and second angle of visual field difference according to an embodiment of the invention The schematic diagram in domain.

Fig. 5 shows viewing area corresponding to first angle of visual field and second angle of visual field difference according to an embodiment of the invention Another schematic diagram in domain.

Fig. 6 shows viewing area corresponding to first angle of visual field and second angle of visual field difference according to an embodiment of the invention Another schematic diagram in domain.

Fig. 7 shows the structural representation of virtual reality helmet according to an embodiment of the invention.

Embodiment

The various exemplary embodiments of the present invention are described in detail now with reference to accompanying drawing.It should be noted that：Unless have in addition Body illustrates that the unlimited system of part and the positioned opposite of step, numerical expression and the numerical value otherwise illustrated in these embodiments is originally The scope of invention.

The description only actually at least one exemplary embodiment is illustrative to be never used as to the present invention below And its application or any restrictions that use.

It may be not discussed in detail for technology, method and apparatus known to person of ordinary skill in the relevant, but suitable In the case of, the technology, method and apparatus should be considered as part for specification.

In shown here and discussion all examples, any occurrence should be construed as merely exemplary, without It is as limitation.Therefore, other examples of exemplary embodiment can have different values.

It should be noted that：Similar label and letter represents similar terms in following accompanying drawing, therefore, once a certain Xiang Yi It is defined, then it need not be further discussed in subsequent accompanying drawing in individual accompanying drawing.

An embodiment provides a kind of image processing method.Fig. 2 is shown according to one implementation of the present invention The process chart of the image processing method of example.Referring to Fig. 2, this method comprises at least step S201 to step S204.

Step S201, obtain first angle of visual field corresponding to image to be displayed, the optical component of virtual reality helmet Corresponding to second angle of visual field and second angle of visual field, the second field range size on the screen of virtual reality helmet；

Step S202, using first angle of visual field, second angle of visual field and the second field range size, the first visual field is calculated Angle is corresponding, the first field range size on the screen of virtual reality helmet；

Step S203, using the first field range size, the size of image to be displayed is calculated；

Step S204, according to the size of image to be displayed, optic aberrance revising processing is carried out to image to be displayed.

In one embodiment of the present of invention, image to be displayed is to be inputted by virtual reality helmet external equipment to virtual Real helmet, first angle of visual field corresponding to image to be displayed is the optical section of the external equipment of virtual reality helmet The angle of visual field of part.The external equipment of virtual reality helmet can be any in camera, video camera.Worn in virtual reality When equipment establishes connection with its external equipment, virtual reality helmet can obtain the device parameter of the external equipment, wherein, if Standby parameter comprises at least the angle of visual field of the optical component of external equipment.By taking video camera as an example, regarded in video camera by what shooting obtained Take place frequently before delivering to virtual reality helmet, video camera need with virtual reality helmet establish connect, when video camera with After virtual reality helmet establishes connection, virtual reality helmet can obtain the relevant parameter of video camera, for example, video camera In lens the angle of visual field.

Distortion occurs in the image that user is watched by the optical component of virtual reality helmet, for example, pincushion is abnormal Become.In order that the image that user is watched by the optical component of virtual reality helmet is consistent with original image, to original Before beginning image is shown, optic aberrance revising processing is carried out to original image.The original image herein being related to is to be shown Image.

In one embodiment of the present of invention, above-mentioned steps S102 is specifically, utilize first angle of visual field, second angle of visual field and Two field range sizes, it is calculated based on following calculating formulas (1) corresponding to first angle of visual field, in virtual reality helmet The first field range size on screen,

R=R* [tan (FOV₁/2)/tan(FOV₂/ 2)]-calculating formula (1),

Wherein, r is zone radius size corresponding to the first field range, and R is zone radius corresponding to the second field range Size, FOV₁For first angle of visual field, FOV₂For second angle of visual field.

After zone radius size corresponding to the first field range is calculated, in one embodiment of the present of invention, it is based on Following calculating formulas (2), the size of image to be displayed is calculated,

R=K₀+K₁*h+K₂*h²+K₃*h³+…+K_n*hⁿ- calculating formula (2),

H is the length of side of square area corresponding to image to be displayed, and r is that zone radius corresponding to the first field range is big It is small, K₀、K₁、K₂、K₃…K_nFor coefficient corresponding to the optical component of virtual reality helmet.

It should be noted that image to be displayed, before by optic aberrance revising processing, image to be displayed is one square Shape image, its corresponding length of side are h.For image to be displayed after optic aberrance revising processing, image to be displayed is changed into half Footpath is the barrel-shaped of r, and radius r herein is corresponding to above-mentioned the first field range being calculated based on above-mentioned calculating formula (1) Zone radius size.In addition, K₀、K₁、K₂、K₃…K_nAs coefficient corresponding to the optical component of virtual reality helmet, be by What optical component determined in itself, when the model of optical component changes, its corresponding coefficient correspondingly changes, its In, K₀、K₁、K₂、K₃…K_nIt can be obtained by being fitted experiment test.

After the size of image to be displayed is calculated, according to the size of image to be displayed, image to be displayed is carried out Optic aberrance revising processing, specifically, first, determines multiple characteristic points, then, according to image to be displayed from image to be displayed Size, each characteristic point is determined to the distance of the central point of image to be displayed, then, based on following calculating formulas (3) to be shown Image carries out optic aberrance revising processing,

L'=K₀+K₁*l+K₂*l²+K₃*l³+…+K_n*lⁿ- calculating formula (3),

Wherein, l is characterized the distance for the central point for a little arriving image to be displayed, K₀、K₁、K₂、K₃、……K_nFor virtual reality head Coefficient corresponding to the optical component of equipment is worn, l' is characterized the center that image to be displayed is a little arrived after optic aberrance revising is handled The distance of point.In the embodiment of the present invention, the multiple characteristic points determined from image to be displayed are preferably to be evenly distributed on to wait to show The characteristic point of diagram picture, each characteristic point determined is subjected to optic aberrance revising processing according to above-mentioned calculating formula (3).

Fig. 3 shows the schematic diagram of optic aberrance revising process according to an embodiment of the invention.Referring to Fig. 3, Fig. 3's Left-half shows two images to be displayed (image a and image b), Fig. 3 right side before optic aberrance revising processing It is divided to and shows two barrel-shaped image (image c and image d) after the processing of two optic aberrance revisings.Image c passes through for image a The image obtained after optic aberrance revising processing.Image b is the image that image d is obtained after optic aberrance revising is handled.From Its central point and a characteristic point are determined in image a, according to image a size, determines this feature point to image a central point Distance, and then above-mentioned calculating formula (3) is based on, optic aberrance revising processing is carried out to this feature point, obtained at optic aberrance revising The distance of this feature point after reason to central point.Its central point and a characteristic point are determined from image b, according to the big of image b It is small, this feature point is determined to the distance of the central point of image, and then above-mentioned calculating formula (3) is based on, optics is carried out to this feature point Distortion correction processing, this feature point after optic aberrance revising processing is obtained to the distance of central point.It is it should be noted that above-mentioned Example illustrate only and a characteristic point is determined from image to be displayed, but not cause any restriction to the present invention.From The quantity for the characteristic point determined in image to be displayed can be it is several, tens, hundreds of, it is even more more.From image to be displayed In the quantity of characteristic point determined it is more, the image obtained after optic aberrance revising processing is more accurate.

After optic aberrance revising processing is carried out to image to be displayed, the image to be displayed after optic aberrance revising is handled Shown on the screen of virtual reality helmet.Image to be displayed after optic aberrance revising processing is in virtual reality head Wear viewing area on the screen of equipment corresponding to first angle of visual field, first on the screen of virtual reality helmet regard Wild range size.First angle of visual field corresponding to image to be displayed and second angle of visual field of the optical component of virtual reality helmet Size following three kinds of situations occur：First angle of visual field is less than second angle of visual field；First angle of visual field is more than second angle of visual field；The One angle of visual field is equal to second angle of visual field.

It is less than the second visual field of the optical component of virtual reality helmet in first angle of visual field corresponding to image to be displayed In the case of angle, referring to Fig. 4, viewing area a is the corresponding to first angle of visual field, on the screen of virtual reality helmet One field range size, viewing area b is corresponding to second angle of visual field, second on the screen of virtual reality helmet regards Wild range size.Viewing area of the image to be displayed on the screen of virtual reality helmet after optic aberrance revising processing For the field range size corresponding to first angle of visual field, on the screen of virtual reality helmet.User passes through virtual reality The region of image to be displayed after the optic aberrance revising processing that the optical component of helmet is watched is first angle of visual field pair The first field range size answer, on the screen of virtual reality helmet.

It is more than the second visual field of the optical component of virtual reality helmet in first angle of visual field corresponding to image to be displayed In the case of angle, referring to Fig. 5, viewing area c is the corresponding to first angle of visual field, on the screen of virtual reality helmet One field range size, viewing area b is corresponding to second angle of visual field, second on the screen of virtual reality helmet regards Wild range size.Viewing area of the image to be displayed on the screen of virtual reality helmet after optic aberrance revising processing For the field range size corresponding to first angle of visual field, on the screen of virtual reality helmet.User passes through virtual reality The region of image to be displayed after the optic aberrance revising processing that the optical component of helmet is watched is second angle of visual field pair The second field range size answer, on the screen of virtual reality helmet.

It is equal to the second visual field of the optical component of virtual reality helmet in first angle of visual field corresponding to image to be displayed In the case of angle, referring to Fig. 6, first angle of visual field is corresponding, the first field range on the screen of virtual reality helmet Size, the second field range corresponding with second angle of visual field, on the screen of virtual reality helmet are equal in magnitude.Optics Viewing area of the image to be displayed on the screen of virtual reality helmet after distortion correction processing is first angle of visual field pair Field range size answer, on the screen of virtual reality helmet.The optics that user passes through virtual reality helmet The region of image to be displayed after the optic aberrance revising processing that part is watched is corresponding to second angle of visual field, in virtual reality The second field range size on the screen of helmet.

Based on same inventive concept, the invention provides a kind of computer-readable recording medium.Computer-readable storage medium Matter is stored with computer program, and the computer program can realize any implementation as described above by one or more computing device The image processing method that example provides.

Based on same inventive concept, the invention provides a kind of virtual reality helmet.Fig. 7 is shown according to the present invention The structural representation of the virtual reality helmet of one embodiment.Referring to Fig. 7, virtual reality helmet 700 includes display Unit 701, virtual image optical unit 702, input operation unit 703, state information acquisition unit 704, communication unit 705, Memory 706, processor 707, graphics processing unit 708, display driver element 709, sound processing unit 710, sound input/ Output unit 711.

Memory 706 is arranged to the mass-memory unit with solid-state drive etc..Memory 706 can store should With program or various types of data.For example, processor 707 performs the computer journey of image processing method provided by the invention Sequence, or, the content that user is watched using virtual reality helmet 700 can be stored in memory 706, etc..

Processor 707, which can include computer processing unit (CPU) or other, has the equipment of similar functions.Some realities Apply in example, processor 707 is used to perform image processing method provided by the invention, that is, performs following operating procedure：Obtain and wait to show Diagram as corresponding to first angle of visual field, virtual reality helmet optical component second angle of visual field and second angle of visual field it is corresponding , the second field range size on the screen of virtual reality helmet；Utilize first angle of visual field, second angle of visual field and Two field range sizes, it is calculated corresponding to first angle of visual field, first visual field on the screen of virtual reality helmet Range size；Using the first field range size, the size of image to be displayed is calculated；According to the size of image to be displayed, Optic aberrance revising processing is carried out to image to be displayed.

Display unit 701 can include display panel, display panel be arranged on virtual reality helmet 700 towards with The side surface of family face can be an entire panel or be the left panel and right panel for corresponding to user's left eye and right eye respectively. Display panel can be electroluminescent (Electroluminescence, abbreviation EL) element, liquid crystal display or be tied with similar The miniscope or retina of structure can directly display or similar laser scan type display.

Virtual image optical unit 702 shoots the image shown by display unit 701 in an exaggerated way, and allows user to press Image shown by the virtual image observation of amplification.Can be from content as the display image being output on display unit 701 The image for the virtual scene that reproduction equipment (Blu-ray Disc or DVD player) or streaming media server provide or use are outside The image for the reality scene that camera 110 is shot.In some embodiments, virtual image optical unit 702 can include lens unit, Such as spherical lens, non-spherical lens, Fresnel Lenses etc..

It should be noted that external camera 110 can be arranged on 700 main body front surface of virtual reality helmet, it is outside Camera 110 can be one or more.External camera 110 can obtain three-dimensional information, and be also used as Distance-sensing Device.In addition, the position sensitive detector (PSD) or other kinds of range sensor of reflected signal of the detection from object can To be used together with external camera 110.External camera 110 and range sensor can be used for detection wearing virtual reality and wear and set Body position, posture and the shape of standby 700 user.In addition, user can directly be seen by external camera 110 under certain condition See or preview reality scene.

Input operation unit 703 include it is at least one be used for performing the functional unit of input operation, such as button, button, Switch or other there is the parts of similar functions, user instruction is received by functional unit, and refer to the output of processor 707 Order.

State information acquisition unit 704 is used for the status information for obtaining the user of wearing virtual reality helmet 700.Shape State information acquisition unit 704 can include various types of sensors, detect status information for itself, and can pass through communication Unit 705 obtains status information from external equipment (such as other multi-functional terminal ends of smart mobile phone, watch and user's wearing).Shape State information acquisition unit 704 can obtain the positional information and/or attitude information on the head of user.State information acquisition unit 704 can include gyro sensor, acceleration transducer, global positioning system (Global Positioning System, Abbreviation GPS) sensor, geomagnetic sensor, doppler effect sensors, infrared sensor, one in radio-frequency field intensity sensor It is individual or multiple.In addition, state information acquisition unit 704 obtains the state letter of the user of wearing virtual reality helmet 700 Breath, such as mode of operation (whether user dresses virtual reality helmet 700), the operating state of user of acquisition user are (all As it is static, walk, run and such mobile status, the posture of hand or finger tip, eyes open or closed state, sight side To, pupil size), the state of mind (whether user is immersed in the shown image of observation and the like), or even physiology State.

Communication unit 705 performs the coding with the communication process of external device (ED), modulation and demodulation processing and signal of communication And decoding process.In addition, processor 707 can send transmission data from communication unit 705 to external device (ED).Communication mode can be with It is wired or wireless, such as mobile high definition link (Mobile High-Definition Link, abbreviation MHL) or logical With universal serial bus (Universal Serial Bus, abbreviation USB), high-definition media interface (High Definition Multimedia Interface, abbreviation HDMI), Wireless Fidelity (Wi-Fi), Bluetooth communication or low-power consumption bluetooth communication, and Mesh network of IEEE802.11s standards etc..In addition, communication unit 705 can be according to WCDMA (Wideband Code Division Multiple Access, abbreviation W-CDMA), Long Term Evolution (Long Term Evolution, referred to as LTE) and similar standard operation cellular radio transceiver.

Graphics processing unit 708 is used to perform signal transacting, for example the picture signal to being exported from processor 707 is related Image quality correction, and the resolution ratio by its conversion of resolution for the screen according to display unit 701.Then, display driving Unit 709 selects the often row pixel of display unit 701 successively, and scans the often row pixel of display unit 701 successively line by line, thus Picture element signal based on the picture signal through signal transacting is provided.

Sound processing unit 710 can perform sound quality correction or the sound of the voice signal exported from processor 707 Amplification, and signal transacting of input audio signal etc..Then, sound I/O unit 711 after acoustic processing to outside Export the sound of sound and input from microphone.

It should be noted that the structure or part in Fig. 7 shown in dotted line frame can be independently of virtual reality helmets 700 Outside, for example, can be arranged in external treatment system (such as computer system) with virtual reality helmet 700 coordinate make With；Or structure shown in dotted line frame or part can be arranged on the inside of virtual reality helmet 700 or surface.

The present invention can be system, method and/or computer program product.Computer program product can include computer Readable storage medium storing program for executing, containing for making processor realize the computer-readable program instructions of various aspects of the invention.

Computer-readable recording medium can keep and store to perform the tangible of the instruction that uses of equipment by instruction Equipment.Computer-readable recording medium for example can be-- but be not limited to-- storage device electric, magnetic storage apparatus, optical storage Equipment, electromagnetism storage device, semiconductor memory apparatus or above-mentioned any appropriate combination.Computer-readable recording medium More specifically example (non exhaustive list) includes：Portable computer diskette, hard disk, random access memory (RAM), read-only deposit It is reservoir (ROM), erasable programmable read only memory (EPROM or flash memory), static RAM (SRAM), portable Compact disk read-only storage (CD-ROM), digital versatile disc (DVD), memory stick, floppy disk, mechanical coding equipment, for example thereon It is stored with punch card or groove internal projection structure and the above-mentioned any appropriate combination of instruction.Calculating used herein above Machine readable storage medium storing program for executing is not construed as instantaneous signal in itself, the electromagnetic wave of such as radio wave or other Free propagations, leads to Cross the electromagnetic wave (for example, the light pulse for passing through fiber optic cables) of waveguide or the propagation of other transmission mediums or transmitted by electric wire Electric signal.

Computer-readable program instructions as described herein can be downloaded to from computer-readable recording medium it is each calculate/ Processing equipment, or outer computer or outer is downloaded to by network, such as internet, LAN, wide area network and/or wireless network Portion's storage device.Network can include copper transmission cable, optical fiber is transmitted, is wirelessly transferred, router, fire wall, interchanger, gateway Computer and/or Edge Server.Adapter or network interface in each calculating/processing equipment receive from network to be counted Calculation machine readable program instructions, and the computer-readable program instructions are forwarded, for the meter being stored in each calculating/processing equipment In calculation machine readable storage medium storing program for executing.

For perform the computer program instructions that operate of the present invention can be assembly instruction, instruction set architecture (ISA) instruction, Machine instruction, machine-dependent instructions, microcode, firmware instructions, condition setup data or with one or more programming languages The source code or object code that any combination is write, programming language-such as Smalltalk of the programming language including object-oriented, C++ etc., and conventional procedural programming languages-such as " C " language or similar programming language.Computer-readable program refers to Order fully can on the user computer be performed, partly performed on the user computer, the software kit independent as one Perform, part performs or completely on remote computer or server on the remote computer on the user computer for part Perform.In the situation of remote computer is related to, remote computer can be by the network of any kind-include LAN Or wide area network (WAN) (LAN)-subscriber computer is connected to, or, it may be connected to outer computer (such as utilize internet Service provider passes through Internet connection).In certain embodiments, believe by using the state of computer-readable program instructions Breath comes personalized customization electronic circuit, such as PLD, field programmable gate array (FPGA) or FPGA Array (PLA), the electronic circuit can perform computer-readable program instructions, so as to realize various aspects of the invention.

Referring herein to method, apparatus (system) and computer program product according to embodiments of the present invention flow chart and/ Or block diagram describes various aspects of the invention.It should be appreciated that each square frame and flow chart of flow chart and/or block diagram and/ Or in block diagram each square frame combination, can be realized by computer-readable program instructions.

These computer-readable program instructions can be supplied to all-purpose computer, special-purpose computer or other programmable datas The processor of processing unit, so as to produce a kind of machine so that these instructions are passing through computer or other programmable datas During the computing device of processing unit, work(specified in one or more of implementation process figure and/or block diagram square frame is generated The device of energy/action.These computer-readable program instructions can also be stored in a computer-readable storage medium, these refer to Order causes computer, programmable data processing unit and/or other equipment to work in a specific way, so as to be stored with instruction Computer-readable medium then includes a manufacture, and it is included in one or more of implementation process figure and/or block diagram square frame The instruction of the various aspects of defined function/action.

Computer-readable program instructions can also be loaded into computer, other programmable data processing units or other In equipment so that series of operation steps is performed on computer, other programmable data processing units or miscellaneous equipment, with production Raw computer implemented process, so that performed on computer, other programmable data processing units or miscellaneous equipment Instruct function/action specified in one or more of implementation process figure and/or block diagram square frame.

Flow chart and block diagram in accompanying drawing show system, method and the computer journey of multiple embodiments according to the present invention Architectural framework in the cards, function and the operation of sequence product.At this point, each square frame in flow chart or block diagram can generation One module of table, program segment or a part for instruction, module, program segment or a part for instruction include one or more be used in fact The executable instruction of logic function as defined in existing.At some as in the realization replaced, the function of being marked in square frame can also To occur different from the order marked in accompanying drawing.For example, two continuous square frames can essentially perform substantially in parallel, it Can also perform in the opposite order sometimes, this is depending on involved function.It is also noted that block diagram and/or flow The combination of each square frame and block diagram in figure and/or the square frame in flow chart, function or action as defined in performing can be used Special hardware based system is realized, or can be realized with the combination of specialized hardware and computer instruction.For this It is well known that, realized for art personnel by hardware mode, realized by software mode and pass through software and hardware With reference to mode realize it is all of equal value.

It is described above various embodiments of the present invention, described above is exemplary, and non-exclusive, and It is not limited to disclosed each embodiment.In the case of without departing from the scope and spirit of illustrated each embodiment, for this skill Many modifications and changes will be apparent from for the those of ordinary skill in art field.The selection of term used herein, purport Best explaining the principle of each embodiment, practical application or to the technological improvement in market, or make the art its Its those of ordinary skill is understood that each embodiment disclosed herein.The scope of the present invention is defined by the appended claims.

Claims

A kind of 1. image processing method, it is characterised in that including：

Obtain image to be displayed corresponding to first angle of visual field, virtual reality helmet optical component second angle of visual field and institute State corresponding to second angle of visual field, the second field range size on the screen of the virtual reality helmet；

Using first angle of visual field, second angle of visual field and the second field range size, described first is calculated The angle of visual field is corresponding, the first field range size on the screen of the virtual reality helmet；

Using the first field range size, the size of the image to be displayed is calculated；

According to the size of the image to be displayed, optic aberrance revising processing is carried out to the image to be displayed.
2. according to the method for claim 1, it is characterised in that first angle of visual field is described corresponding to the image to be displayed The angle of visual field of the optical component of the external equipment of virtual reality helmet.
3. according to the method for claim 2, it is characterised in that first angle of visual field corresponding to image to be displayed is obtained, including：

When the virtual reality helmet and the external equipment are established and connected, the virtual reality helmet obtains institute The device parameter of external equipment is stated, wherein, the device parameter includes the angle of visual field of the optical component of the external equipment.
4. according to the method for claim 1, it is characterised in that using first angle of visual field, second angle of visual field and The second field range size, it is calculated corresponding to first angle of visual field, in the screen of the virtual reality helmet The first field range size on curtain, including：

The first field range size is calculated based on following calculating formula,

R=R* [tan (FOV₁/2)/tan(FOV₂/ 2)], wherein, r is zone radius size corresponding to first field range, R is zone radius size, FOV corresponding to second field range₁For first angle of visual field, FOV₂For second visual field Angle.
5. according to the method for claim 1, it is characterised in that utilize the first field range size, institute is calculated The size of image to be displayed is stated, including：

The size of the image to be displayed is calculated based on following calculating formula,

R=K₀+K₁*h+K₂*h²+K₃*h³+…+K_n*hⁿ, wherein, h is the side of square area corresponding to the image to be displayed Long, r is zone radius size, K corresponding to first field range₀、K₁、K₂、K₃、……K_nWear and set for the virtual reality Coefficient corresponding to standby optical component.
6. according to any described methods of claim 1-5, it is characterised in that according to the size of the image to be displayed, to institute State image to be displayed and carry out optic aberrance revising processing, including：

Multiple characteristic points are determined from the image to be displayed, according to the size of the image to be displayed, determine that each characteristic point arrives The distance of the central point of the image to be displayed；

Optic aberrance revising processing is carried out to the image to be displayed based on following calculating formula,

L'=K₀+K₁*l+K₂*l²+K₃*l³+…+K_n*lⁿ, wherein, l be characterized a little to the image to be displayed central point away from From K₀、K₁、K₂、K₃、……K_nFor coefficient corresponding to the optical component of the virtual reality helmet, l ' is the characteristic point The distance of the central point of the image to be displayed is arrived after optic aberrance revising is handled.
7. according to the method for claim 1, it is characterised in that methods described also includes：

Image to be displayed after optic aberrance revising is handled is shown on the screen of the virtual reality helmet.
8. according to the method for claim 7, it is characterised in that the image to be displayed after optic aberrance revising is handled is in institute State after being shown on the screen of virtual reality helmet, be less than the feelings of second angle of visual field in first angle of visual field Under condition, treated after the optic aberrance revising processing that user is watched by the optical component of the virtual reality helmet The region of display image is corresponding to first angle of visual field, first visual field on the screen of the virtual reality helmet Range size；

In the case where first angle of visual field is more than second angle of visual field, user passes through the virtual reality helmet The region of image to be displayed after the optic aberrance revising processing that optical component is watched is corresponding for second angle of visual field , the second field range size on the screen of the virtual reality helmet；

In the case where first angle of visual field is equal to second angle of visual field, user passes through the virtual reality helmet The region of image to be displayed after the optic aberrance revising processing that optical component is watched is corresponding for second angle of visual field , the second field range size on the screen of the virtual reality helmet.
9. a kind of computer-readable recording medium, the computer-readable recording medium storage has computer program, and its feature exists In, the computer program by one or more computing device to realize the image as described in claim any one of 1-8 Processing method.
10. a kind of virtual reality helmet, including memory, processor and it is stored on the memory and can be at the place The computer program run on reason device, it is characterised in that realize that right such as will described in the computing device during computer program Seek the image processing method described in any one of 1-8.