CN103067728B - A kind of processing method of bore hole 3D rendering and device - Google Patents

Abstract

This application discloses a kind of processing method and device of bore hole 3D rendering, wherein, described in this, method is applied to electronic display unit, and described method comprises: the position of human eye information obtaining N number of user, N be more than or equal to 1 integer; According to the position of human eye information of described N number of user, judge whether N number of vision area corresponding to described N number of user be to being positive vision area; If described N number of vision area centering has M vision area to being in described positive vision area, adjust by described i-th vision area to the neighbouring viewing zones of both sides and i-th vision area at least one the vision area image in the vision area formed, wherein, 1≤M≤N, 1≤i≤M, and i, M are integer; If described N number of vision area centering has P vision area to being in described inversion district, adjust by a described kth vision area to the neighbouring viewing zones of both sides and a kth vision area at least one the vision area image in the vision area formed, wherein, 1≤P≤N, 1≤k≤M, and k, P are integer.

Description

A kind of processing method of bore hole 3D rendering and device

Technical field

The present invention relates to image display technology field, particularly a kind of processing method of bore hole 3D rendering and device.

Background technology

At present, along with the development of image display technology, commercially there is the electronic equipment of 3D class, such as 3D TV.People soon object time, the image that two eyes are formed on the retina is also incomplete same, and left eye sees that the left surface of object is more, and right eye sees that the right flank of object is more, these two pictures through brain comprehensively after produce stereoscopic vision, 3D Display Technique utilizes this principle to present stereo-picture exactly.

3D Display Technique has bore hole formula and the large class of spectacle two.Bore hole 3D Display Technique mainly comprises optical barrier type technology and lens pillar technology.The two displaying principle is close, and be all that the visual fusion of two different angles of applicable images of left and right eyes being watched shows together, see Fig. 1, image, by being arranged on the grating 12 before display screen 11, forms multiple vision area.Fig. 1 describes the vision area structure of multiple views.Vision area 1, vision area 2, vision area 3, vision area 4, vision area 5 and vision area 6 is a vision area group.In same vision area group, each vision area presents the left and right view with certain parallax successively.

User is when watching image, if images of left and right eyes is in the neighbouring viewing zones of same vision area group, the left and right view that this neighbouring viewing zones presents enters the images of left and right eyes of user respectively, and user just can see stereo-picture.Adjacent two vision areas in same vision area group are positive vision area, and the user be in positive vision area can see stereo-picture.Such as in FIG, user's left eye is in the vision area 3 of the first vision area group 001, right eye is in the vision area 4 of the first vision area group 001, this user just can see stereo-picture, if user's left eye is in the vision area 4 of the first vision area group 001, right eye is in the vision area 5 of the first vision area group 001, and this user also can see stereo-picture.

Certainly, user not necessarily can be in positive vision area always, also may be in inversion district, namely inversion district is the neighbouring viewing zones being in the different vision area group in vision area circle 13 both sides, such as, user's left eye is in the vision area 6 of the first vision area group 001, and right eye is in the vision area 1 of the second vision area group 002, then now user is then in inversion district.

The applicant, in the process realizing the application, finds in actual applications, even if user's human eye is in positive vision area, still can be subject to, with the interference of residing vision area neighbouring viewing zones image, affecting viewing effect.See Fig. 1, user's left eye is in the vision area 3 of the first vision area group 001, and the image that right eye is in vision area 4, first vision area group 001 vision area 2 of the first vision area group 001 can enter user's left eye, and the image of the first vision area group 001 vision area 5 can enter user's right eye.Like this, vision area 2 can produce crosstalk and ghost image to vision area 3, vision area 5 can produce crosstalk and ghost image to vision area 4.Now, when user watches, then can produce crosstalk and ghost image to user's human eye, affect user's viewing effect to a certain extent.

Therefore, the technical problem that prior art exists is: the image in positive vision area can be subject to the interference of the vision area image adjacent with positive vision area both sides, produces crosstalk and ghost image, affects the viewing effect of user.

Summary of the invention

The invention provides a kind of processing method and device of bore hole 3D rendering, the interference of the vision area image adjacent with positive vision area both sides can be subject in order to the image solved in the positive vision area that exists in prior art, produce the technical problem of crosstalk and ghost image.

On the one hand, the present invention, by an embodiment of the application, provides following technical scheme:

A processing method for bore hole 3D rendering, described method is applied to electronic display unit, and described method comprises: the position of human eye information obtaining N number of user, N be more than or equal to 1 integer; According to the position of human eye information of described N number of user, judge whether N number of vision area corresponding to described N number of user be to being positive vision area; If described N number of vision area centering has M vision area to being in described positive vision area, adjust by i-th vision area to the neighbouring viewing zones of both sides and i-th vision area at least one the vision area image in the vision area formed, wherein, 1≤M≤N, 1≤i≤M, and i, M are integer; If described N number of vision area centering has P vision area to being in inversion district, adjust by a kth vision area to the neighbouring viewing zones of both sides and a kth vision area at least one the vision area image in the vision area formed, wherein, 1≤P≤N, 1≤k≤M, and k, P are integer.

On the other hand, the present invention is provided by another embodiment of the application:

A processing unit for bore hole 3D rendering, states device and comprises: acquiring unit, for obtaining the position of human eye information of N number of user, N be more than or equal to 1 integer; First judging unit, for the position of human eye information according to described N number of user, judges whether N number of vision area corresponding to described N number of user be to being positive vision area; First adjustment unit, if having M vision area to being in described positive vision area for described N number of vision area centering, adjust by i-th vision area to the neighbouring viewing zones of both sides and i-th vision area at least one the vision area image in the vision area formed, wherein, 1≤M≤N, 1≤i≤M, and i, M are integer; Second adjustment unit, if having P vision area to being in inversion district for described N number of vision area centering, adjust by a kth vision area to the neighbouring viewing zones of both sides and a kth vision area at least one the vision area image in the vision area formed, wherein, 1≤P≤N, 1≤k≤M, and k, P are integer.

One or more technical schemes in technique scheme, have following technique effect or advantage:

In one or more technical schemes of the application, by obtaining the position of human eye information of user, judge in multiple user, have which user to be in positive vision area, and which user is in inversion district.And at least one the vision area image in the vision area neighbouring viewing zones of both sides and this vision area are made up of vision area in the positive vision area of corresponding adjustment or inversion district, the impact that the image aligning vision area with the neighbouring viewing zones optionally reducing these positive vision area both sides brings because of parallax, or vision area, on because user's parallax gives other vision areas on the impact brought, can solve the problem of crosstalk and ghost image effectively.

Accompanying drawing explanation

Fig. 1 is the vision area structure chart of multiple views in prior art;

Fig. 2 is the flow chart of the processing method of bore hole 3D rendering in the embodiment of the present application;

Fig. 3 is the effective coverage schematic diagram of display screen in the embodiment of the present application;

Fig. 4 is the coordinate system schematic diagram of the positional information of locating human eye in the embodiment of the present application;

Fig. 5 is that in the embodiment of the present application, user is in the schematic diagram in the vision area structure of multiple views;

Fig. 6 adjusts i-th vision area to the flow chart of the image of at least one vision area in the neighbouring viewing zones of both sides in the embodiment of the present application;

Fig. 7 is that in the embodiment of the present application, two users are in the schematic diagram in the vision area structure of multiple views;

Fig. 8 is that in the embodiment of the present application, two spaced users of tool are in the schematic diagram in the vision area structure of multiple views;

The flow chart of Fig. 9 to be the neighbouring viewing zones of vision area both sides, user place in the embodiment of the present application be not the first interval vision area;

Figure 10 is that in the embodiment of the present application, four users are in the schematic diagram in the vision area structure of multiple views;

Figure 11 is that in the embodiment of the present application, three users are in the schematic diagram in the vision area structure of multiple views;

Figure 12 is the schematic diagram in the embodiment of the present application with two vision area groups;

Figure 13 is process flow figure when being in the embodiment of the present application in different vision area group;

Figure 14 is that in the embodiment of the present application, a user is in positive vision area, and a user is in the schematic diagram in inversion district;

Figure 15 is that in the embodiment of the present application, two users are in positive vision area, and a user is in the schematic diagram in inversion district;

Figure 16 is the schematic diagram of the processing unit of bore hole 3D rendering in the embodiment of the present application.

Embodiment

In order to the image solved in the positive vision area that exists in prior art can be subject to the interference of the vision area image adjacent with positive vision area both sides, produce the technical problem of crosstalk and ghost image, the embodiment of the present invention proposes a kind of processing method and device of bore hole 3D rendering, and its solution general thought is as follows:

In this application, provide a kind of processing method and device of bore hole 3D rendering, first the method obtains N number of left eye positional information of N number of left eye eyeball of N number of user and N number of right eye positional information of N number of right eye eyeball, N be more than or equal to 1 integer; According to N number of left eye positional information and N number of right eye positional information, judge whether N number of vision area corresponding to N number of user be to being positive vision area; If N number of vision area centering has M vision area to being in positive vision area, adjust i-th vision area to the image of at least one vision area in the neighbouring viewing zones of both sides, M is the integer being more than or equal to 1 and being less than or equal to N, to reduce the interference that the vision area image adjacent with positive vision area both sides aligns the image in vision area, the problem of crosstalk and ghost image effectively can be solved.

Below by accompanying drawing and specific embodiment, technical solution of the present invention is described in detail, the specific features being to be understood that in the embodiment of the present invention and embodiment is the detailed description to technical solution of the present invention, instead of the restriction to technical solution of the present invention, when not conflicting, the technical characteristic in the embodiment of the present invention and embodiment can combine mutually.

Embodiment one:

In the embodiment of the present application, a kind of processing method of bore hole 3D rendering is proposed.

Further, the method is applied to electronic display unit.

Electronic display unit in the embodiment of the present application can for the television set that user's bore hole can be made to watch 3D.

Please refer to Fig. 2 below, the specific implementation process of the processing method of bore hole 3D rendering is as follows:

S201, obtains the position of human eye information of N number of user, N be more than or equal to 1 integer.

N be more than or equal to 1 integer.

S202, according to the position of human eye information of N number of user, judges whether N number of vision area corresponding to N number of user be to being positive vision area.

S203, if N number of vision area centering has M vision area to being in positive vision area, adjust by i-th vision area to the neighbouring viewing zones of both sides and i-th vision area at least one the vision area image in the vision area formed.

Wherein, 1≤M≤N, 1≤i≤M, and i, M are integer.Wherein, M is the integer being more than or equal to 1 and being less than or equal to N, a user namely may be only had to be in positive vision area, or multiple user belongs to positive vision area, or N number of user belongs to positive vision area.In addition, i is arbitrary integer between 1 to M.

S204, if N number of vision area centering has P vision area to being in inversion district, adjust by a kth vision area to the neighbouring viewing zones of both sides and a kth vision area at least one the vision area image in the vision area formed.

Wherein, 1≤P≤N, 1≤k≤M, and k, P are integer.The implication of this scope is: likely only have a user to be in inversion district, or multiple user is in inversion district, or N number of user is in inversion district, and a kth vision area is to one of the vision area centering for being in the user in inversion district.

Concrete, in S201, electronic display unit for bore hole 3D display has the identification equipment identifying position of human eye information, this identification equipment comprises camera and position computation module, camera is positioned at the front end of display screen, can be built in electronic display unit, also can be external, for obtaining the facial image being positioned at display screen front.Position computation module is built in the data processing chip of television display equipment, extracts human eye information from facial image, then extracts the positional information of human eye from the human eye information got.

And in the process gathered, when when the user watching TV is more, always there are some users, they are not within the scope of effective viewing, at this moment, obtain their position of human eye information, belong to non-productive work.Therefore when obtaining the positional information of human eye, then effective viewing areas can be set.Such as in figure 3, set by display screen, the radial viewing area being D=3 rice with the vertical range of display screen is effective coverage, and the user watched within this region is validated user.The position of human eye information obtaining the user within this scope is effective position of human eye information.User outside this scope, because normally can not watch display frame, therefore also need not obtain the position of human eye information of these users, or can ignore the position of human eye information of these users got.

Further, when obtaining position of human eye information, because people is that two eyes are watched simultaneously, therefore, the position of human eye packets of information that can get user contains two information, i.e. left eye positional information and right eye positional information.

Further, position of human eye information is represented by coordinate.

The three-dimensional system of coordinate that the coordinate system of the positional information of location human eye is is initial point with display screen geometric center, as the coordinate system described in Fig. 4, base plate plane is the diagrammatic plan of display screen, the origin of coordinates is in display screen geometric center, x represents the horizontal range between human eye and the origin of coordinates, y represents the vertical range between human eye and the origin of coordinates, and z represents the viewing distance between human eye and display screen.

Therefore, the coordinate figure of the right and left eyes of human eye just can be expressed as:

(x is left, and y is left, and z is left) and (x is right, and y is right, and z is right).

Wherein, this D coordinates value can locate position of human eye more accurately, is convenient to vision area residing for follow-up accurate Calculation human eye.

Those skilled in the art should know, when human eye viewing distance z limits, the viewing distance such as limiting human eye is in the distance regions perpendicular to display screen 3 meters to 5 meters, and the user outside this interval is not considered as effectively watching user.Now, position of human eye information can be the two-dimensional coordinate (x, y) with horizontal range x and vertical range y.In like manner, when y limits, such as be limited to range coordinate initial point vertical range be the user that watches in the interval of 1 meter to 2 meters for effectively to watch user, then position of human eye information can be the two-dimensional coordinate (x, z) with horizontal range x and viewing distance z.

In the present embodiment, electronic display unit is opened simultaneously, then automatically start the positional information that identification equipment obtains human eye.

In order to tackle in viewing process, user has the situation of shift position, then can arrange identification equipment, such as arranges and again to obtain at interval of the scheduled time (such as 10 minutes) and to upgrade a position of human eye information.Can also monitoring modular be increased in identification equipment, carry out real-time monitoring, move once monitor user, just start acquisition and renewal that identification equipment re-starts position of human eye information.The startup of identification equipment is not limited only to start shooting and automatically opens, and can also be started, such as remote controller operation etc. by the external control of user.

After obtaining position of human eye information, then can judge whether the vision area residing for user's human eye is positive vision area, i.e. positive vision area.

Now, then can perform S202: according to the position of human eye information of N number of user, judge whether N number of vision area corresponding to N number of user be to being positive vision area.

Concrete, there is a relation correspondence table in electronic display unit, according to this relation correspondence table, can judge whether vision area residing for human eye is positive vision area, and the left eye of user's human eye and the concrete residing vision area of right eye.

The positive vision area data area (X, Y, Z) prestored can set, and specifically uses coordinate range ([x1, x2], [y1, y2], [z1, z2]) to represent.

The positive vision area scope such as set is specially ([1,10], [1,10], [3,5]), then the user in this range areas is in the user in positive vision area.

If with user's citing, the position of human eye rectangular space coordinate obtained in step S201 (x is left, and y is left, and z is left) and (x is right, and y is right, and z is right) seemingly, now then can compare respectively at the positive view data prestored by other user class.When the position of human eye rectangular space coordinate value got is all in the range intervals of the above-mentioned positive view data prestored, namely [x1 is all dropped on an x left side and the x right side, x2] in, a y left side and the y right side are all dropped in [y1, y2], and [z1 is all dropped on a z left side and the z right side, z2] interior time, namely judge that the human eye got is in positive vision area, otherwise, judge that human eye is in inversion district.

Now, except judging whether human eye is in except positive vision area, the concrete vision area residing for human eye can also be determined.Such as according to mapping table, the human eye that can determine in Fig. 1 is in vision area 3 and vision area 4, is in positive vision area.

If when there is multiple user, then according to left eye positional information and the right eye positional information of each user, the vision area residing for multiple user, and can judge in multiple user, have which user to be present in positive vision area.

More specifically, after obtaining the user be in positive vision area, then S203 can be performed.

Because each user has left eye and right eye, so i-th vision area centering in S203 contains two sub-vision areas simultaneously, i.e. the left vision area of user and right vision area.

Concrete, in S203, have two kinds of situations, namely user is in the situation of positive vision area, or at least two users are in the situation of positive vision area, and rear extended meeting is described in detail both of these case.

Processing mode concrete in S203, is the vision area of the vision area both sides be in positive vision area adjusted, such as please refer to Fig. 5, describe the vision area structure of multiple views in Fig. 5.Vision area 1, vision area 2, vision area 3, vision area 4, vision area 5 and vision area 6 is same vision area group.In same vision area group, by the effect of grating, each vision area presents the left and right view with certain parallax successively.If there is a user to be in Figure 5 in positive vision area, the left eye of such as user is in vision area 3, and the right eye of user is in vision area 4.So in S203, then at least can adjust the image of at least one vision area in the both sides vision area adjacent with vision area 4 with vision area 3.Such as adjust the image in vision area 2, or the image in adjustment vision area 5, or adjust the image in vision area 2 and vision area 5 simultaneously, to reduce the interference to vision area residing for this user of vision area 2 and/or vision area 5.

Concrete adjustment mode, is by the image of vision area Image Adjusting vision area residing for human eye of the human eye vision area both sides be in positive vision area, or is adjusted to monochrome image.

As Fig. 5, being then be image in vision area 3 by the Image Adjusting in vision area 2, is the image in vision area 4 by the Image Adjusting in vision area 5.Or be monochrome image by the Image Adjusting in vision area 2 and vision area 5.

In addition, can also only adjust a vision area in vision area 2 and vision area 5.

The topmost object of above-mentioned adjustment, it is the crosstalk reducing vision area 2 and/or vision area 5 pairs of user place vision areas, namely do not have the image of parallax to replace the most easily causing the image of the neighbouring viewing zones of crosstalk and ghost image with user's images of left and right eyes, thus user's human eye is not it is seen that have the image of crosstalk and ghost image or less crosstalk and ghost image.

Monochrome image in the present embodiment is black image, is namely equivalent to not show any image, thus there is not interference and ghost problems.

More specifically, in S203, adjust i-th vision area to the image of at least one vision area in the neighbouring viewing zones of both sides, concrete adjustment mode please refer to Fig. 6, as follows:

S601, judges i-th vision area is the first interval vision area to whether there being at least one vision area in the neighbouring viewing zones of both sides, the first interval vision area specifically in N number of vision area to the vision area outside scope.

S602, if i-th vision area is all the first interval vision area to there being a vision area to be the first interval vision area or i-th vision area in the neighbouring viewing zones of both sides to the neighbouring viewing zones of both sides, judges whether the vision area adjacent with the opposite side of the first interval vision area belongs to N number of vision area pair.

If so, Image Adjusting in first interval vision area is monochrome image by S603.

S604, if not, is the image of i-th vision area centering by the Image Adjusting in the first interval vision area, or is monochrome image by the Image Adjusting in the first interval vision area.

The vision area that interval vision area does not specifically have users, when user's bore hole viewing 3D electronic display unit, likely there will be the situation that a vision area has multiple user, also likely there is the situation not having user in vision area, if the neighbouring viewing zones of vision area does not have other users shared by user, this so adjacent with user vision area is then interval vision area.

Than as shown in Figure 5, in Figure 5, vision area 3 and vision area 4 be a user right and left eyes respectively residing for vision area, other vision areas not shared by user are then the first interval vision area, vision area 1 in Figure 5, vision area 2, vision area 5, vision area 6, all not shared by user, therefore, is all interval vision area.

If vision area is respectively vision area 3 and vision area 4 residing for user's right and left eyes, in S601, first judge in the neighbouring viewing zones of these vision area both sides, user place, whether have at least one vision area to be the first interval vision area.

In Figure 5, the vision area adjacent with vision area 3 is vision area 2, and the vision area adjacent with vision area 4 is vision area 5, therefore in S601, then judges whether vision area 2 and vision area 5 have at least one vision area to be the first interval vision area.

Judged result is now as described in S602, and vision area 2 and vision area 5 are all the first interval vision area.Then further judge the vision area 1 adjacent with vision area 2, and the vision area adjacent with vision area 56 is whether shared by other users.

Now, please refer to Fig. 5, there will be vision area 1 and the situation of vision area 6 not shared by other users.

Further, then the processing mode in S604 can be performed.

The first: the image in vision area 2 and vision area 5 is all adjusted to monochrome image.

The second: be the image in vision area 3 by the Image Adjusting in vision area 2, and be the image in vision area 4 by the Image Adjusting in vision area 5.

Disposition when the above is a user.And the situation below also existing when a user.

Such as vision area residing for this user is to being vision area 1 and vision area 2, now in a vision area group, vision area 1 left side does not have vision area, neighbouring viewing zones 3 is had in vision area 2, now then vision area 3 can be adjusted to monochrome image or be adjusted to the image in vision area 2, to reduce its string shadow interference right to vision area residing for user.

If when having two users or multiple user, concrete disposition is more complicated than a disposition during user.

When having two users, please refer to Fig. 7 and Fig. 8.

What all represent in Fig. 7 and Fig. 8 is the vision area structure of multiple views.Vision area 1, vision area 2, vision area 3, vision area 4, vision area 5, vision area 6, vision area 7, vision area 8, vision area 9, vision area 10 is a vision area group.In same vision area group, each vision area presents the left and right view with certain parallax successively.

Now, if having two users, the particular location of two users can have two kinds of situations below:

The first situation: first user is in vision area 3 and vision area 4, second user is in vision area 5 and vision area 6.Concrete, the first situation please refer to Fig. 7.

The second situation: first user is in vision area 3 and vision area 4, second user is in vision area 7 and vision area 8.Concrete, the first situation please refer to Fig. 8.

Certainly, first user and the second user can transpositions, and the processing mode after change place is the same with the processing mode of two kinds of situations above.

For the first situation.First perform S601, judge whether with the neighbouring viewing zones (vision area 2 and vision area 5) of vision area both sides residing for first user be the first interval vision area.

Now can judge, vision area 2 is the first interval vision area, and vision area 5 is not the first interval vision area.

The step in S602 can be performed afterwards, namely judge whether vision area 1 and vision area 6 belong within vision area scope shared by other users.

Now can draw judged result: vision area 1 does not belong to vision area shared by user, vision area 6 is vision areas shared by the second user.

Further, according to the result judged, then can perform S603, vision area 2 is adjusted to monochrome image.

Further, for the second user, determining step above also can be used.In prediction on such basis, then the vision area 7 adjacent with the second user can be adjusted to the image in vision area 6, or vision area 7 is adjusted to monochrome image.

Processing mode concrete when this is adjacent for two users, and concrete, the technical scheme of neighbouring viewing zones, the Image Adjusting both sides image used in positive vision area can be paid the utmost attention to.

If for the second situation, namely first user is in vision area 3 and vision area 4, second user is in the situation of vision area 7 and vision area 8, now according to step above, for first user, can be then the image in vision area 3 by the Image Adjusting in vision area 2, simultaneously by the image that the Image Adjusting in vision area 5 is in vision area 4, to reduce vision area 2 and the right crosstalk of vision area 5 pairs of first user place vision areas.For the second user, then can be the image in vision area 7 by the Image Adjusting in vision area 6, simultaneously by the image that the Image Adjusting in vision area 9 is in vision area 8, to reduce vision area 6 and vision area 9 crosstalk right to the second user place vision area.Or for first user and the second user, simultaneously by vision area 2, vision area 5, vision area 6, vision area 9 is adjusted to monochrome image, to reduce its first user place vision area to the crosstalk right with the second user place vision area.

If now have three or multiple user, and processing method is above similar, repeats no more in this application.

Certainly, also have a kind of situation, such as first user is in vision area 3 and vision area 4, second user is in vision area 6 and vision area 7.Now, according to reckoning, then can be monochrome image by the Image Adjusting in vision area 5, and to pay the utmost attention to the Image Adjusting in vision area 2 be image in vision area 3, to reduce neighbouring viewing zones, both sides to vision area residing for first user to crosstalk.In addition, can be also the image in vision area 7 by the Image Adjusting in vision area 8, to reduce the crosstalk right to vision area residing for the second user.Certainly, can be also monochrome image by the Image Adjusting in the image in vision area 2 and vision area 8 simultaneously.

And for the determining step in S601, if there is multiple user, situation about also having below occurs: namely the neighbouring viewing zones of user place vision area both sides is not the first interval vision area, all there is user in namely adjacent vision area.

Concrete processing method is then as shown in Figure 9:

S901, if i-th vision area is not the first interval vision area to the neighbouring viewing zones of both sides, judges that whether two vision areas of i-th vision area centering are all overlapping with other vision areas of N number of vision area centering.

S902, if when the left vision area of i-th vision area centering is overlapping, be the image in the left vision area of the i-th+1 vision area centering by the Image Adjusting in the right vision area of i-th vision area centering.

S903, when the right vision area of i-th vision area centering is overlapping, then by image that the Image Adjusting in the left vision area of i-th vision area is in the right vision area of t vision area centering.

Wherein, the right vision area that t vision area is right is adjacent with the right left vision area of i-th vision area.And t is arbitrary integer between 1 to M.

S904, if when two of i-th vision area centering vision areas are not overlapping with other vision areas of N number of vision area centering, by the image that the Image Adjusting in the left vision area of i-th vision area centering is in the right vision area of t vision area centering, the right vision area that t vision area is right is adjacent with the right left vision area of i-th vision area, is the image in the left vision area of the i-th+1 vision area centering by the Image Adjusting in the right vision area of i-th vision area centering.

According to step above, there will be following several situation.

First, in S901, if i-th vision area is not the first interval vision area to the neighbouring viewing zones of both sides, then illustrate that there are other vision areas the adjacent both sides of i-th vision area centering to existence, and may have with other vision areas overlapping situation, now, then can judge that whether two vision areas of i-th vision area centering are all overlapping with other vision areas of N number of vision area centering further.

Now there will be situation below, in S902, then describe the situation that the left vision area of i-th vision area centering is overlapping with the vision area of other vision area centerings.As shown in Figure 10, such as first user is in vision area 1 and vision area 2, second user is then in vision area 2 and vision area the 3, three user is in vision area 4 and vision area 5.The right vision area that the left vision area that now vision area residing for the second user is right is right with vision area residing for first user is overlapping, is overlapped in vision area 2.In order to ensure the viewing effect of first user and the 3rd user, then by the right vision area Image Adjusting left vision area image that vision area is right residing for the 3rd user of vision area centering residing for the second user.Namely being equivalent to the viewing effect of reduction by second user, is the image in vision area 4 by the Image Adjusting in vision area 3.

Further, according to the treatment step in Fig. 6, can be also the image in vision area 5 by the Image Adjusting in the vision area 6 in Figure 10, to ensure the viewing effect of the 3rd user, reduce the serial interference that vision area 6 is right to the 3rd user place vision area.

And the situation in S903 and the image in S902 similar, unique difference is that the right vision area of the second user is overlapping with the left vision area of the 3rd user.Namely the situation that now vision area residing for user is right is: vision area residing for first user is to being vision area 1 and vision area 2; Vision area residing for second user is to being vision area 3 and vision area 4; Vision area residing for 3rd user is to being vision area 4 and vision area 5.Now, then reducing the viewing effect of the second user, by the right vision area of the vision area centering residing for first user of the Image Adjusting in the left vision area of the second user, is the image in vision area 2 by the Image Adjusting in vision area 3.

Further, according to the treatment step in Fig. 6, can be also the image in vision area 5 by the Image Adjusting in the vision area 6 in Figure 10, to ensure the viewing effect of the 3rd user, reduce the serial interference that vision area 6 is right to the 3rd user place vision area.

As shown in figure 11, if there are three users, such as first user is in vision area 1 and vision area 2, second user is then in vision area vision area 3 and vision area the 4, three user is in vision area 5 and vision area 6 for situation in S904.

Now, for the second user, then the vision area that both sides are adjacent is all within the scope of other user's vision areas.

Now, then by image that the Image Adjusting in the vision area 3 at the second user place is in vision area 2, Image Adjusting in vision area 4 is the image in vision area 5, namely the viewing effect of reduction by second user is equivalent to, ensure the viewing effect of first user and the 3rd user, reduce the serial interference of the second user place vision area to the vision area of first user and the 3rd user.

Further, according to the treatment step in Fig. 6, can be also the image in vision area 6 by the Image Adjusting in the vision area 7 in Figure 11, to ensure the viewing effect of the 3rd user, reduce the serial interference that vision area 7 is right to the 3rd user place vision area.

Above-described situation, be the situation that all users are in positive vision area, and in a practical situation, not all user can both be present in positive vision area, some users can be in inversion district, specifically please refer to Figure 12.

There are in Figure 12 two vision area groups, as user's images of left and right eyes is in the neighbouring viewing zones of the different vision area group in two vision area group both sides respectively, the right side then in figure, left view enter the images of left and right eyes of user respectively, and the view of entanglement can make user produce the bad reactions such as dizzy, eye is swollen.Such as, user's left eye is in the vision area 6 of the first vision area group, and right eye is in the vision area 1 of the second vision area group, what this vision area 6 presented is right view, and what this vision area 1 presented is left view, and such user's left eye is it is seen that right view, right eye, it is seen that left view, enters the image entanglement of user's human eye.Therefore, using adjacent two vision areas in different vision area group as inversion district.

When user's human eye is in inversion district, enter the image entanglement of user's human eye, user can be made to produce the bad reactions such as dizzy, eye is swollen.

And for have user be in inversion district time, then can perform the step in S204: if N number of vision area centering has P vision area to being in inversion district, adjust by a kth vision area to the neighbouring viewing zones of both sides and a kth vision area at least one the vision area image in the vision area formed.

Concrete thought is probably as follows:

When user's human eye is in inversion district, not only to takes into account the image entanglement problem of access customer human eye, also will consider the interference problem of neighbouring viewing zones.The embodiment of the present invention is selected preferential to solve image entanglement problem, and by the vision area residing for the Image Adjusting human eye of positive vision area adjacent with vision area residing for human eye, the left and right view that positive vision area is presented enters the images of left and right eyes of user respectively, remedial frames entanglement problem.Further, then solve the interference problem of neighbouring viewing zones, the image of left and right two neighbouring viewing zones of vision area residing for adjustment human eye.

And more specifically, concrete processing mode as shown in figure 13.

S1301, judges whether a P vision area centering kth vision area is the second interval vision area at least one side-looking district in the neighbouring viewing zones of both sides.

Second interval vision area specifically in N number of vision area to the vision area outside scope.P is more than or equal to the integer that 1 is less than or equal to N.

S1302, if the neighbouring viewing zones Zhong You side vision area of a kth vision area to both sides is the second interval vision area, be that a kth vision area centering is away from the image in the sub-vision area of the second interval vision area by the Image Adjusting of a kth vision area centering in the sub-vision area of the second interval vision area.

S1303, if a kth vision area is all the second interval vision area to the neighbouring viewing zones of both sides, after then the left vision area Image Adjusting of a kth vision area centering being the image in the right vision area of a kth vision area centering, be the image in the vision area adjacent with the right vision area of a kth vision area centering by the Image Adjusting in the right vision area of a kth vision area centering; Or after being the left vision area image of a kth vision area centering, be the vision area image adjacent with the left vision area of a kth vision area centering by a kth vision area centering left vision area Image Adjusting by the right vision area Image Adjusting of a kth vision area centering.

Specific implementation process above can be divided into a user and multiple user to perform.

When only having a user to be in inversion district.User in such as Figure 12, left eye is in the vision area 6 of the first vision area group, and right eye is in the vision area 1 of the second vision area group.

First, judge vision area 5 adjacent with vision area 6 respectively, and whether the vision area 2 adjacent with vision area 1 is the second interval vision area.

Now can obtain judged result is situation about describing in S1303: vision area 5 and vision area 2 are all the second interval vision areas.Now can make to adjust in two ways.

The first: be the image in the vision area 1 of the second vision area group by the Image Adjusting in the vision area 6 of the first vision area group, make to be in the image that the user's right and left eyes in inversion district sees consistent, present 2D image.Further, 3D rendering is seen in order to user can be made, be with the image in the vision area 2 of group by the Image Adjusting in the vision area 1 of the second vision area group, and be (because the Image Adjusting in original vision area 6 is the image of vision area 1 with the image organizing vision area 6 by the Image Adjusting in the vision area 5 of the first vision area group, therefore now by image that the Image Adjusting in vision area 5 is vision area 6, being actually the Image Adjusting in vision area 5 is image in vision area 1), to reduce the crosstalk of vision area 5 pairs of vision areas 6.

The second: be the image in the vision area 6 of the first vision area group by the Image Adjusting in the vision area 1 of the second vision area group, makes to be in the image that the user's right and left eyes in inversion district sees consistent, presents 2D image.Further, 3D rendering is seen in order to user can be made, be with the image in the vision area 5 of group by the Image Adjusting in the vision area 6 of the first vision area group, and be (because the Image Adjusting in original vision area 1 is the image of vision area 6 with the image organizing vision area 1 by the Image Adjusting in the vision area 2 of the second vision area group, therefore now by image that the Image Adjusting in vision area 2 is vision area 1, being actually the Image Adjusting in vision area 2 is image in vision area 6), to reduce the crosstalk of vision area 2 pairs of vision areas 1.

If have two users, and first user is in inversion district, the second user is in positive vision area, and when residing for two users, vision area centering has interval vision area, the disposition when situation of process and above a user are in inversion district is similar.

As situation about describing in Figure 14, the left eye of first user is in the vision area 6 of the first vision area group, and right eye is in the vision area 1 of the second vision area group; The left eye of the second user is in vision area 3 and the vision area 4 of the second vision area group.

Now, for first user, then can be the image in the vision area 1 of the second vision area group by the Image Adjusting in the vision area 6 of the first vision area group, consistent to make to be in the image that the user's right and left eyes in inversion district sees, present 2D image.Or being the image of the vision area 6 of the first vision area group by the Image Adjusting of the vision area 1 of the second vision area group, showing image in dedicating user 2D to.

Further, owing to there is interval vision area 2 in the vision area 1 in same vision area group and vision area 3.Now, in order to mutual viewing effect can not be affected, can be monochrome image by the Image Adjusting in vision area 2.

Further, in the step in S1301, also there is the situation that the neighbouring viewing zones Zhong You side vision area of a kth vision area to both sides is the second interval vision area.As shown in figure 15, in two vision area groups, the left eye of first user is in the vision area 6 of the first vision area group, and right eye is in the vision area 1 of the second vision area group; The left eye of the second user is in vision area 5 and the vision area 6 of the first vision area group; The left eye of the 3rd user is in vision area 3 and the vision area 4 of the second vision area group.

Now, then can perform the step in S1302, be the image in the vision area 6 of the first vision area group by the Image Adjusting in the vision area 1 of the second vision area group, ensure the viewing effect of first user with this, make first user watch the image of 2D.

Further, can be also monochrome image by the Image Adjusting of the vision area 2 of the second vision area group, and be that in concrete adjustment mode above-described embodiment, tool is described later in detail, and repeats no more in this application with the image in the vision area 5 of group by the Image Adjusting in the vision area 4 of the first vision area group.

Further, in the judgement in S1301, also there is a kth vision area to the neighbouring viewing zones of both sides is not the second interval vision area, then not to a kth vision area to processing, namely abandon the viewing of the user be in this vision area, nurse one's health the viewing effect of other vision areas.

Above described embodiment describes the detailed process of the processing method of bore hole 3D rendering, first by collecting the eye position information of N number of user, then the eye position information by collecting has judged which user is in positive vision area, then to vision area residing for the user be in positive vision area to or the adjacent vision area of this vision area to both sides adjust, reduce with this interference that vision area image adjacent with positive vision area both sides aligns the image in vision area.

And more specifically, be then the neighbouring viewing zones first judging the both sides that vision area residing for user is right whether be the first interval vision area.This judgement has multiple situation, and the situation different according to each has different processing modes.Such as: vision area residing for user is to there being vision area vision area residing for the first interval vision area or user to be all the first interval vision area to the neighbouring viewing zones of both sides in the neighbouring viewing zones of both sides, whether the vision area that so then the opposite side of continuation judgement and the first interval vision area is adjacent belongs to N number of vision area pair, if now estimate of situation is yes, then show that two vision areas are only spaced a vision area to centre, in order to not affect the viewing effect of two users, so then the vision area at this interval is adjusted to monochrome image; If estimate of situation is no, then show vision area residing for two users between be at least spaced two vision areas, now, vision area residing for user can be adjusted to the image (concrete adjustment mode is with reference to the adjustment mode in Fig. 8) of corresponding vision area centering to adjacent vision area by prioritizing selection.

In addition, except adjusting in positive vision area, can also to the vision area be in inversion district to adjusting, if have P vision area to being in inversion district than N number of vision area centering, adjust by a kth vision area to the neighbouring viewing zones of both sides and a kth vision area at least one the vision area image in the vision area formed.Concrete, first also can judge whether a P vision area centering kth vision area is the second interval vision area at least one vision area in the neighbouring viewing zones of both sides, and judged result is multiple, has different processing modes according to different judged results.If a kth vision area is all the second interval vision area to the neighbouring viewing zones of both sides, after then the left vision area Image Adjusting of a kth vision area centering being the image in the right vision area of a kth vision area centering, be the image in the vision area adjacent with the right vision area of a kth vision area centering by the Image Adjusting in the right vision area of a kth vision area centering; Or after being the left vision area image of a kth vision area centering, be the vision area image adjacent with the left vision area of a kth vision area centering by a kth vision area centering left vision area Image Adjusting by the right vision area Image Adjusting of a kth vision area centering.Adjustment herein, first solves image entanglement problem, and by the vision area residing for the Image Adjusting human eye of positive vision area adjacent with vision area residing for human eye, the left and right view that positive vision area is presented enters the images of left and right eyes of user respectively, remedial frames entanglement problem.And then carry out other process.

To sum up, in the embodiment of the present application, by obtaining the position of human eye information of user, judge in multiple user, have which user to be in positive vision area, and which user is in inversion district.And at least one the vision area image in the vision area neighbouring viewing zones of both sides and this vision area are made up of vision area in the positive vision area of corresponding adjustment or inversion district, the impact that the image aligning vision area with the neighbouring viewing zones optionally reducing these positive vision area both sides brings because of parallax, or vision area, on because user's parallax gives other vision areas on the impact brought, can solve the problem of crosstalk and ghost image effectively.

The following examples specifically describe the processing unit of a kind of bore hole 3D rendering corresponding to the method.

Embodiment two:

In the embodiment of the present application, a kind of processing unit of bore hole 3D rendering is described.

Please refer to Figure 16 below, this device comprises:

Acquiring unit 1601, for N number of right eye positional information of the N number of left eye positional information and N number of right eye eyeball that obtain N number of left eye eyeball of N number of user, N be more than or equal to 1 integer;

First judging unit 1602, for according to N number of left eye positional information and N number of right eye positional information, judges whether N number of vision area corresponding to N number of user be to being positive vision area;

First adjustment unit 1603, if have M vision area to being in positive vision area for N number of vision area centering, adjust i-th vision area to the image of at least one vision area in the neighbouring viewing zones of both sides, M is the integer being more than or equal to 1 and being less than or equal to N, wherein, i is arbitrary integer between 1 to M.

Second adjustment unit 1604, if having P vision area to being in inversion district for N number of vision area centering, adjust by a kth vision area to the neighbouring viewing zones of both sides and a kth vision area at least one the vision area image in the vision area formed, wherein, 1≤P≤N, 1≤k≤M, and k, P are integer.

Further, the first adjustment unit 1603, specifically comprises:

Second judging unit, for judging that i-th vision area is the first interval vision area to whether there being at least one vision area in the neighbouring viewing zones of both sides, the first interval vision area specifically in N number of vision area to the vision area outside scope;

3rd judging unit, if be all first interval vision area to there being a vision area to be the first interval vision area or i-th vision area in the neighbouring viewing zones of both sides to the neighbouring viewing zones of both sides for i-th vision area, judge whether the vision area adjacent with the opposite side of the first interval vision area belongs to N number of vision area pair;

If so, 3rd adjustment unit, for being monochrome image by the Image Adjusting in the first interval vision area;

4th adjustment unit, for if not, is the image of i-th vision area centering by the Image Adjusting in the first interval vision area, or is monochrome image by the Image Adjusting in the first interval vision area.

Further, this device also comprises:

4th judging unit, for judging whether to have during i-th vision area is to the neighbouring viewing zones of both sides after at least one vision area is the first interval vision area, if i-th vision area is not the first interval vision area to the neighbouring viewing zones of both sides, judge that whether i-th vision area centering, two vision areas are all overlapping with other vision areas of N number of vision area centering;

5th adjustment unit, if overlapping for the left vision area of i-th vision area centering time, be the image in the left vision area of the i-th+1 vision area centering by the Image Adjusting in the right vision area of i-th vision area centering.

6th adjustment unit, for when the right vision area of i-th vision area centering is overlapping, then by the image that the Image Adjusting in the left vision area of i-th vision area is in the right vision area of t vision area centering, the right vision area that t vision area is right is adjacent with the right left vision area of i-th vision area, and t is arbitrary integer between 1 to M.

Further, this device also comprises the 7th adjustment unit, for after judging that whether i-th vision area centering, two vision areas are all overlapping with other vision areas of N number of vision area centering, if when two of i-th vision area centering vision areas are not overlapping with other vision areas of N number of vision area centering, by the image that the Image Adjusting in the left vision area of i-th vision area centering is in the right vision area of t vision area centering, the right vision area that t vision area is right is adjacent with the right left vision area of i-th vision area, it is the image in the left vision area of the i-th+1 vision area centering by the Image Adjusting in the right vision area of i-th vision area centering.

Further, the second adjustment unit 1604 also comprises:

5th judging unit, for judging that whether N number of vision area of N number of user is to after being in positive vision area, if N number of vision area centering has P vision area to being in inversion district, judge whether a P vision area centering kth vision area is the second interval vision area at least one vision area in the neighbouring viewing zones of both sides, second interval vision area specifically in N number of vision area to the vision area outside scope, P is more than or equal to the integer that 1 is less than or equal to N;

8th adjustment unit, if be the second interval vision area for a kth vision area to there being a vision area in the neighbouring viewing zones of both sides, be that a kth vision area centering is away from the image in the sub-vision area of the second interval vision area by the Image Adjusting of a kth vision area centering in the sub-vision area of the second interval vision area;

9th adjustment unit, if be all the second interval vision area for a kth vision area to the neighbouring viewing zones of both sides, after then the left vision area Image Adjusting of a kth vision area centering being the image in the right vision area of a kth vision area centering, be the image in the vision area adjacent with the right vision area of a kth vision area centering by the Image Adjusting in the right vision area of a kth vision area centering; Or after being the left vision area image of a kth vision area centering, be the vision area image adjacent with the left vision area of a kth vision area centering by a kth vision area centering left vision area Image Adjusting by the right vision area Image Adjusting of a kth vision area centering.

By one or more embodiment of the present invention, following technique effect can be realized:

Above-mentioned two detailed processes that described in the embodiments the processing method of bore hole 3D rendering, first by collecting the eye position information of N number of user, then the eye position information by collecting has judged which user is in positive vision area, then to vision area residing for the user be in positive vision area to or the adjacent vision area of this vision area to both sides adjust, reduce with this interference that vision area image adjacent with positive vision area both sides aligns the image in vision area.

And more specifically, be then the neighbouring viewing zones first judging the both sides that vision area residing for user is right whether be the first interval vision area.This judgement has multiple situation, and the situation different according to each has different processing modes.Such as: vision area residing for user is to there being vision area vision area residing for the first interval vision area or user to be all the first interval vision area to the neighbouring viewing zones of both sides in the neighbouring viewing zones of both sides, whether the vision area that so then the opposite side of continuation judgement and the first interval vision area is adjacent belongs to N number of vision area pair, if now estimate of situation is yes, then show that two vision areas are only spaced a vision area to centre, in order to not affect the viewing effect of two users, so then the vision area at this interval is adjusted to monochrome image; If estimate of situation is no, then show vision area residing for two users between be at least spaced two vision areas, now, vision area residing for user can be adjusted to the image (concrete adjustment mode is with reference to the adjustment mode in Fig. 8) of corresponding vision area centering to adjacent vision area by prioritizing selection.

In addition, except adjusting in positive vision area, can also to the vision area be in inversion district to adjusting, if have P vision area to being in inversion district than N number of vision area centering, adjust by a kth vision area to the neighbouring viewing zones of both sides and a kth vision area at least one the vision area image in the vision area formed.Concrete, first also can judge whether a P vision area centering kth vision area is the second interval vision area at least one vision area in the neighbouring viewing zones of both sides, and judged result is multiple, has different processing modes according to different judged results.If a kth vision area is all the second interval vision area to the neighbouring viewing zones of both sides, after then the left vision area Image Adjusting of a kth vision area centering being the image in the right vision area of a kth vision area centering, be the image in the vision area adjacent with the right vision area of a kth vision area centering by the Image Adjusting in the right vision area of a kth vision area centering; Or after being the left vision area image of a kth vision area centering, be the vision area image adjacent with the left vision area of a kth vision area centering by a kth vision area centering left vision area Image Adjusting by the right vision area Image Adjusting of a kth vision area centering.Adjustment herein, first solves image entanglement problem, and by the vision area residing for the Image Adjusting human eye of positive vision area adjacent with vision area residing for human eye, the left and right view that positive vision area is presented enters the images of left and right eyes of user respectively, remedial frames entanglement problem.And then carry out other process.

To sum up, in the embodiment of the present application, by obtaining the position of human eye information of user, judge in multiple user, have which user to be in positive vision area, and which user is in inversion district.And at least one the vision area image in the vision area neighbouring viewing zones of both sides and this vision area are made up of vision area in the positive vision area of corresponding adjustment or inversion district, the impact that the image aligning vision area with the neighbouring viewing zones optionally reducing these positive vision area both sides brings because of parallax, or vision area, on because user's parallax gives other vision areas on the impact brought, can solve the problem of crosstalk and ghost image effectively.

Those skilled in the art should understand, embodiments of the invention can be provided as method, system or computer program.Therefore, the present invention can adopt the form of complete hardware embodiment, completely software implementation or the embodiment in conjunction with software and hardware aspect.And, the present invention can adopt and (include but not limited to magnetic disc store in one or more computer-usable storage medium wherein including computer usable program code, CD-ROM, optical memory etc.) form of the upper computer program implemented.

The present invention describes with reference to according to the flow chart of the method for the embodiment of the present invention, equipment (system) and computer program and/or block diagram.Should understand can by the combination of the flow process in each flow process in computer program instructions realization flow figure and/or block diagram and/or square frame and flow chart and/or block diagram and/or square frame.These computer program instructions can being provided to the processor of all-purpose computer, special-purpose computer, Embedded Processor or other programmable data processing device to produce a machine, making the instruction performed by the processor of computer or other programmable data processing device produce device for realizing the function of specifying in flow chart flow process or multiple flow process and/or block diagram square frame or multiple square frame.

These computer program instructions also can be stored in can in the computer-readable memory that works in a specific way of vectoring computer or other programmable data processing device, the instruction making to be stored in this computer-readable memory produces the manufacture comprising command device, and this command device realizes the function of specifying in flow chart flow process or multiple flow process and/or block diagram square frame or multiple square frame.

These computer program instructions also can be loaded in computer or other programmable data processing device, make on computer or other programmable devices, to perform sequence of operations step to produce computer implemented process, thus the instruction performed on computer or other programmable devices is provided for the step realizing the function of specifying in flow chart flow process or multiple flow process and/or block diagram square frame or multiple square frame.

Obviously, those skilled in the art can carry out various change and modification to the present invention and not depart from the spirit and scope of the present invention.Like this, if these amendments of the present invention and modification belong within the scope of the claims in the present invention and equivalent technologies thereof, then the present invention is also intended to comprise these change and modification.

Claims (10)

1. a processing method for bore hole 3D rendering, described method is applied to electronic display unit, it is characterized in that, described method comprises:

Obtain the position of human eye information of N number of user, N be more than or equal to 1 integer;

According to the position of human eye information of described N number of user, judge whether N number of vision area corresponding to described N number of user be to being positive vision area;

If described N number of vision area centering has M vision area to being in described positive vision area, adjust by i-th vision area to the neighbouring viewing zones of both sides and i-th vision area at least one the vision area image in the vision area formed, wherein, 1≤M≤N, 1≤i≤M, and i, M are integer;

If described N number of vision area centering has P vision area to being in inversion district, adjust by a kth vision area to the neighbouring viewing zones of both sides and a kth vision area at least one the vision area image in the vision area formed, wherein, 1≤P≤N, 1≤k≤M, and k, P are integer.

2. the method for claim 1, is characterized in that, described adjustment by described i-th vision area to the neighbouring viewing zones of both sides and i-th vision area at least one the vision area image in the vision area formed, specifically comprise:

Judge described i-th vision area is the first interval vision area to whether there being at least one vision area in the neighbouring viewing zones of both sides, described first interval vision area specifically in described N number of vision area to the vision area outside scope;

If described i-th vision area is all described first interval vision area to there being a vision area to be the first interval vision area or described i-th vision area in the neighbouring viewing zones of both sides to the neighbouring viewing zones of both sides, judge whether the vision area adjacent with the opposite side of described first interval vision area belongs to described N number of vision area pair;

If so, be monochrome image by the Image Adjusting in described first interval vision area;

If not, be the image of described i-th vision area centering vision area adjacent with described first interval vision area by the Image Adjusting in described first interval vision area, or be described monochrome image by the Image Adjusting in described first interval vision area.

3. method as claimed in claim 2, is characterized in that, whether judge to have during described i-th vision area is to the neighbouring viewing zones of both sides after at least one vision area is the first interval vision area described, described method also comprises:

If described i-th vision area is not the first interval vision area to the neighbouring viewing zones of both sides, judge that whether two vision areas of described i-th vision area centering are all overlapping with other vision areas of described N number of vision area centering;

If when the left vision area of described i-th vision area centering is overlapping, be the image in the left vision area of the i-th+1 vision area centering by the Image Adjusting in the right vision area of described i-th vision area centering;

When the right vision area of described i-th vision area centering is overlapping, then by image that the Image Adjusting in the left vision area of described i-th vision area is in the right vision area of t vision area centering, the right vision area that described t vision area is right is adjacent with the right left vision area of described i-th vision area, and t is arbitrary integer between 1 to M.

4. method as claimed in claim 3, is characterized in that, described judge that whether two vision areas of described i-th vision area centering all overlapping with other vision areas of described N number of vision area centering after, described method also comprises:

If when two vision areas of described i-th vision area centering are not overlapping with other vision areas of described N number of vision area centering, by the image that the Image Adjusting in the left vision area of described i-th vision area centering is in the right vision area of described t vision area centering, the right vision area that t vision area is right is adjacent with the right left vision area of described i-th vision area, is the image in the left vision area of described the i-th+1 vision area centering by the Image Adjusting in the right vision area of described i-th vision area centering.

5. the method for claim 1, is characterized in that, described adjustment by a described kth vision area to the neighbouring viewing zones of both sides and a kth vision area at least one the vision area image in the vision area formed, specifically also comprise:

Judge whether a described P vision area centering kth vision area is the second interval vision area at least one vision area in the neighbouring viewing zones of both sides, described second interval vision area specifically in described N number of vision area to the vision area outside scope;

If a described kth vision area is described second interval vision area to there being a vision area in the neighbouring viewing zones of both sides, be that a described kth vision area centering is away from the image in the sub-vision area of described second interval vision area by the Image Adjusting of a described kth vision area centering in the sub-vision area of described second interval vision area;

If a described kth vision area is all described second interval vision area to the neighbouring viewing zones of both sides, after then the left vision area Image Adjusting of a described kth vision area centering being the image in the right vision area of a described kth vision area centering, be the image in the vision area adjacent with the right vision area of a described kth vision area centering by the Image Adjusting in the right vision area of a described kth vision area centering; Or after being the left vision area image of a described kth vision area centering, be the vision area image adjacent with the left vision area of a described kth vision area centering by a described kth vision area centering left vision area Image Adjusting by the right vision area Image Adjusting of a described kth vision area centering.

6. a processing unit for bore hole 3D rendering, is characterized in that, described device comprises:

Acquiring unit, for obtaining the position of human eye information of N number of user, N be more than or equal to 1 integer;

First judging unit, for the position of human eye information according to described N number of user, judges whether N number of vision area corresponding to described N number of user be to being positive vision area;

First adjustment unit, if having M vision area to being in described positive vision area for described N number of vision area centering, adjust by i-th vision area to the neighbouring viewing zones of both sides and i-th vision area at least one the vision area image in the vision area formed, wherein, 1≤M≤N, 1≤i≤M, and i, M are integer;

Second adjustment unit, if having P vision area to being in inversion district for described N number of vision area centering, adjust by a kth vision area to the neighbouring viewing zones of both sides and a kth vision area at least one the vision area image in the vision area formed, wherein, 1≤P≤N, 1≤k≤M, and k, P are integer.

7. device as claimed in claim 6, it is characterized in that, described first adjustment unit, specifically comprises:

Second judging unit, for judging that described i-th vision area is the first interval vision area to whether there being at least one vision area in the neighbouring viewing zones of both sides, described first interval vision area specifically in described N number of vision area to the vision area outside scope;

3rd judging unit, if be all described first interval vision area to there being a vision area to be the first interval vision area or described i-th vision area in the neighbouring viewing zones of both sides to the neighbouring viewing zones of both sides for described i-th vision area, judge whether the vision area adjacent with the opposite side of described first interval vision area belongs to described N number of vision area pair;

If so, 3rd adjustment unit, for being monochrome image by the Image Adjusting in described first interval vision area;

4th adjustment unit, for if not, is the image of described i-th vision area centering vision area adjacent with described first interval vision area by the Image Adjusting in described first interval vision area, or is described monochrome image by the Image Adjusting in described first interval vision area.

8. device as claimed in claim 7, it is characterized in that, described device also comprises:

4th judging unit, for judging whether to have during described i-th vision area is to the neighbouring viewing zones of both sides after at least one vision area is the first interval vision area, if described i-th vision area is not the first interval vision area to the neighbouring viewing zones of both sides, judge that whether described i-th vision area centering two vision areas are all overlapping with other vision areas of described N number of vision area centering;

5th adjustment unit, if overlapping for the left vision area of described i-th vision area centering time, be the image in the left vision area of the i-th+1 vision area centering by the Image Adjusting in the right vision area of described i-th vision area centering;

6th adjustment unit, for when the right vision area of described i-th vision area centering is overlapping, then by image that the Image Adjusting in the left vision area of described i-th vision area is in the right vision area of t vision area centering, the right vision area that described t vision area is right is adjacent with the right left vision area of described i-th vision area, and t is arbitrary integer between 1 to M.

9. device as claimed in claim 8, it is characterized in that, described device also comprises:

7th adjustment unit, for after judging that whether described i-th vision area centering two vision areas are all overlapping with other vision areas of described N number of vision area centering, if when two vision areas of described i-th vision area centering are not overlapping with other vision areas of described N number of vision area centering, by the image that the Image Adjusting in the left vision area of described i-th vision area centering is in the right vision area of described t vision area centering, the right vision area that t vision area is right is adjacent with the right left vision area of described i-th vision area, it is the image in the left vision area of described the i-th+1 vision area centering by the Image Adjusting in the right vision area of described i-th vision area centering.

10. device as claimed in claim 6, it is characterized in that, described second adjustment unit specifically comprises:

5th judging unit, for judging whether a described P vision area centering kth vision area is the second interval vision area at least one vision area in the neighbouring viewing zones of both sides, described second interval vision area specifically in described N number of vision area to the vision area outside scope;

8th adjustment unit, if be described second interval vision area for a described kth vision area to there being a vision area in the neighbouring viewing zones of both sides, be that a described kth vision area centering is away from the image in the sub-vision area of described second interval vision area by the Image Adjusting of a described kth vision area centering in the sub-vision area of described second interval vision area;

9th adjustment unit, if be all described second interval vision area for a described kth vision area to the neighbouring viewing zones of both sides, after then the left vision area Image Adjusting of a described kth vision area centering being the image in the right vision area of a described kth vision area centering, be the image in the vision area adjacent with the right vision area of a described kth vision area centering by the Image Adjusting in the right vision area of a described kth vision area centering; Or after being the left vision area image of a described kth vision area centering, be the vision area image adjacent with the left vision area of a described kth vision area centering by a described kth vision area centering left vision area Image Adjusting by the right vision area Image Adjusting of a described kth vision area centering.