FR2865829A1 - METHOD FOR CREATING SELECT AND DISPLAYING DIGITAL IMAGES WITH A TERMINAL - Google Patents

Abstract

The invention lies in the technological field of creating and communicating digital images. The invention relates to a method which allows, from a terminal (1, 2), to create, select and display previously recorded digital images. The invention relates more particularly to a method for controlling the display of digital images. a digital image (10), selected from a collection of digital images (9-N), according to the following steps: first, creating a composite image (8), formed of individual images (9-17), the composite image (8) being subdivided into a plurality of substantially contiguous zones, called "tiles", and each individual image (9-17) having a given size and location in the composite image (8) corresponding to a tile ; secondly, displaying the composite image (8) and activating each tile of the composite image (8) as a pointer to obtain an enlarged display of the individual image (10) corresponding to the selected tile.

Description

METHOD FOR CREATING SELECT AND DISPLAYING IMAGES

DIGITAL WITH TERMINAL

  TECHNICAL FIELD The invention lies in the technological field of creating, communicating, and displaying digital images. The invention more specifically relates to a method that allows, from a terminal or a server, to create a digital image containing several images; the method then allows, from a terminal comprising control and display means, to select for display, an image included in the previously created container image.

  STATE OF THE ART The communication of digitized images, for example from photographs, is greatly promoted by communication networks such as the Internet. Digital images are usually stored or stored in servers that can be distant from each other. The network, such as the Internet, provides access to these images with various terminals equipped with control means (eg button keypads, joystick) and display. These terminals are for example PCs (Personal Computer), or mobile terminals such as cellular phones, PDAs (Personal Data Assistant).

  The images can also be stored in the telininals, and in this case, no connection to the network is needed to find them. Images are stored as image collections. An image collection generally includes a plurality of images. The terminals for displaying these images are provided with a keyboard and a display screen. In the case of mobile or portable terminals, the display screens are often small. The user of a teiminal with a display screen who wishes to display an image, needs to perform several operations, using the keyboard of the terminal. If the user wants, for example, to display an image extracted from an image collection, to display it, he must execute various successive operations, for example by using the keyboard of the terminal: open the application allowing the display; select the image collection; select the image of the album; open the image file; optionally, zooming or moving by translation in the image; close the image file; select another image; open the file of this other image; close the file of this other image; etc. This therefore requires a fairly high number of operations that must be executed frame by frame, in the case where the user needs to view several images of a collection, before sending them, for example, to a recipient. The term "recipient" generally refers to a terminal; the terminal is remote from a server, can communicate with this server, and the terminal can display images.

  During these operations of opening and closing successive image files, carried out frame by frame, the problem is that the user is embarrassed by the heaviness and the time necessary to execute, with the keyboard of teiminal, all the operations or manipulations mentioned above. In the case where the user needs to view several images, he must in particular open and close, for each image displayed, the file corresponding to each of these images. It is therefore interesting and necessary to alleviate the problem, allowing a faster and more user-friendly image selection and display. DISCLOSURE OF THE INVENTION The problem of the prior art results in an excessive number of openings and fimetures of image files, when the user of the terminal needs to display images encoded each in an image file. The goal is to provide a faster and more user-friendly interface for the user who wants to easily search for digital images, and display these images on his terminal. The solution is an interface that allows better inter-image and intra-image navigation, in order to reduce the number of operations to be performed by the user with his terminal. Such an interface is performed at the terminal by creating so-called "container" image files each formed of individual images. The advantage of this navigation is even greater with terminals, such as mobile phones or PDAs, which have a limited graphical interface.

  The invention solves the aforementioned problem with a display method of displaying a digital image, selected from a collection of digital images, the method comprising the following steps: first, automatic creation of a composite image, called "image" "container", formed of individual images (selected), the containing image being subdivided into a plurality of substantially contiguous zones, called "tiles", and each individual image respectively having dimensions and a determined location in the containing image corresponding to a tile; secondly, automatically displaying the containing image and activating each tile of the containing image as a pointer to the individual image data corresponding to said tile, and, in response to the selection by a user of one of the tiles , enlarged automatic display of the individual image corresponding to the selected tile.

  The invention also relates to a terminal provided with control and display means, and comprising software for implementing the display control method of an image according to the invention.

  The containing image is created by preferentially using the principle of "tiles" of the JPEG 2000 known image compression method. The JPEG 2000 compression method allows the image to be automatically cut into zones called "tiles". The areas or tiles cutting the containing image are generally rectangular and identical in their geometry. These areas accommodate the selected individual images in the initial image collection, one image per zone or tile; then each selected image to be integrated into an area of the containing image is encoded independently of the other selected images. The image data corresponding to the set of individual images of the containing image are included in the same digital file, and each tile points to a subset of data in the file. Each empty zone or tile of the containing image, that is to say not including an image, is foimed with pixels of uniform color, for example white, over the entire surface of the empty zone, so as to minimize the size in bytes of the containing image. An advantage of the invention is that each tile of the containing image can be activated individually, for example with a tile selection cursor controlled by bidirectional control, for displaying, modifying, or erasing an image or part of it. image it contains, without having to decode-encode the entire image containing. The encoding of each of the individual images included in each zone or tile of the containing image is made in such a way that the image selected and intended to be integrated in a tile of the containing image respects the aspect ratio ( dimension ratio between width and height) of the tiles of the containing image. The image data of each tile is compressed data of the corresponding initial image. An edge of white pixels allows for example to adjust the selected image to integrate in a tile with the dimensions of the tile. The dimensions and location of the individual image in the containing image are preferably determined automatically; but they can also be determined manually by the user with an appropriate interface of the terminal.

  The selected image displayed in a tile is adapted to the capabilities and dimensions of the screen of the terminal used, for example a portable terminal, so as to provide the user with good viewing conditions, allowing him to easily recognize an image individual in a contained image.

  In a particular embodiment of the invention, the containing image may contain individual images of different resolutions. The containing image is preferentially subdivided into nine tiles that can respectively comprise nine individual images. Each of these individual or thumbnail images is selectable, for example with nine corresponding keys of a keypad of the terminal. One of the advantages of the invention is to allow the user to then select a second image of the containing image by a single click, or a simple input, without having to close the file of the first image selected, without having to look for the second image in the initial collection, and without having to open the file of this second image. This is because the image data corresponding to the set of individual images composing a containing image are included in the same digital file, and in which each tile points to a subset of data of the digital file.

  The full-screen display is an enlarged display of an individual thumbnail of the containing image, such that all pixels composing the displayed magnified image are distributed over substantially the entire surface of the terminal screen; but not on the entirety of said surface. However, in an alternative embodiment, full-screen display also means that all the pixels of the image displayed according to the second resolution fill the entire surface of the screen, that is to say 100 % of the screen area. In this last embodiment (100% full-screen display), an available resolution corresponding to an image size immediately greater than the size of the screen is preferably adopted, and the image is decimated so as to obtain the best compromise between the aspect ratio of the screen and the aspect ratio of the image. The aspect ratio characterizes the ratio between the width and the height (of the screen or the image). The image is displayed in full screen, so that one of the dimensions of the image substantially corresponds to a dimension of the screen. The available resolutions are provided by existing standard formats, such as JPEG 2000. JPEG 2000 preferentially allows you to create files with five different resolutions. From the maximum resolution corresponding to the initial image selected, the dimensions (width and height) of the image are divided by two to go to a lower resolution, and so on. The display of the image can thus be adapted to the dimensions of the screen, while minimizing the volume of data to be decoded.

  An advantageous embodiment of the invention makes it possible to produce the enlarged display of the selected individual image in full screen, that is to say with an enlargement such that one of the dimensions of the image corresponds substantially to a dimension of a screen display of a teiiiiinal, presenting, in addition to all the pixels of this first selected image that fills virtually the entire surface of the screen, a portion of the pixels of at least one other image not selected, and also part of the containing image. This embodiment corresponds to a full screen display such that all the pixels constituting the first selected image displayed do not fill the entire surface of the screen. This allows to display a portion of the pixels of at least one other unselected image contiguous or adjacent to the first selected image. Inter-image navigation is improved in this way.

  An objective of the method according to the invention is to allow, to select directly, that is to say for example by a single click, in a second step, with the keyboard of the terminal, and from the display of the first image selected, at least one other image not selected at first.

  The selection of the image to be displayed in full screen (enlarged), and adapted to the dimensions of the screen, is performed either by clicking on the image chosen in the displayed image, that is to say by activating , as a pointer, the corresponding tile of the containing image, or, in an alternative embodiment, by entering an alphanumeric code corresponding for example to the positioning of the chosen image in the containing image. The alphanumeric code that corresponds to the positioning of the image in the containing image is preferably a number or a number. This alphanumeric code is for example displayed in the containing image, either inside each of the thumbnails included in the containing image, or around each of these thumbnails.

  An object of the method according to the invention is also to enlarge by zooming, with the keyboard of the terminal, a part of the selected image displayed in full screen in the second resolution.

  Another object of the method according to the invention is also to translate, with the keyboard of the terminal, part of the displayed zoomed image, so as to display another part of this previously zoomed image.

  The method according to the invention is preferably implemented in a network environment of the Internet type, using a teiminal mobile, such as for example a cell phone, or a PDA. But the method can also be implemented on a PC. The method is applicable to image files stored in a server, or in the PC, or in the mobile terminal. The creation of the containing image is carried out for example in the server, from images transmitted remotely, to the server, from the mobile terminal or the PC. The display of the containing image is then operated in the mobile terminal or the PC, from the image data to be displayed transmitted from the server communicating with these terminals.

  The method according to the invention makes it possible to provide a solution for deleting all the opening and closing operations of each image file of a set of images, by using a contained image encoded in the form of a file. unique image. The user can thus directly display the selected image, from the thumbnail he points to, on the screen of his terminal. The selected image is thus displayed, enlarged and adapted to the screen of the terminal, from the display of a containing image that includes the thumbnail (in a lower resolution) corresponding to the selected image to be displayed in full. screen.

  Other characteristics will appear on reading the description which follows, made with reference to the various figures.

Description of the drawing figures

  FIG. 1 represents an example of a communication network environment in which the method according to the invention is implemented.

  FIG. 2 represents a terminal for implementing the method according to the invention, and displaying a containing image with display areas.

  FIG. 3 represents an image selected according to the method of the invention, and displayed in full screen on the terminal.

  Figure 4 shows a zoomed portion of a selected image according to Figure 3.

  FIG. 5 represents a portion of an image according to FIG. 4, for which a translation of said image portion is made in the display screen.

  FIG. 6 represents a diagram of implementation of the method according to the invention.

  Fig. 7 shows a container image comprising a set of images.

  Description of embodiments

  The following description is a detailed description of the main embodiments of the invention, with reference to the figures, in which the same numerical references identify the same elements in each of the different figures.

  FIG. 1 represents an example of a network environment comprising terminals 1, 2 provided with display means for implementing the method according to the invention. In a preferred embodiment, the method is implemented using a mobile terminal 1, provided with a keyboard 7 and a display screen 6.

  The mobile terminal 1 is advantageously a cellular phone or a PDA. The terminal 1 communicates with other computers 2, 3 in a digital communication network, such as the Internet. Interactive communications of digital images can be operated, for example between the terminal 1 and a remote server 3. The server 3 makes it possible to store digital images, for example in the form of an image collection 9 to N (or 9-N). The image collection is for example an album that includes a plurality of 9-N digital images. The terminal 2 is for example a PC type computer. The links 4 and 5 which allow the communication of digital data between the terminal 1 and the PC 2 on the one hand, then between the terminal 1 and the server 3 on the other hand, are operated in a network such as GSM (Global System for Mobile), GPRS (General Packet Radio System), WIFI. The protocols used to communicate are, for example, of the Hyper Text Transmission Protocol (HTTP) type, with the Multimedia Message Service (MMS) infrastructure. According to other embodiments, the link 4 between the terminals 1 and 2 may also be a wired link, or a wireless link of the infrared or bluetooth type.

  With the means of the prior art, when the user of the terminal 1, 2 needs to view one or, more generally, several digital images, it executes successively an opening of the application or software for viewing the image; a selection of the 9-N image collection, if these images 9 to N are stored in a folder or a directory (album); a selection of a local image file (if the image is stored in the terminal 1) or remote (if the image is stored in the server 3) in the folder; an opening of the selected image file, which allows a display of the image on the screen 6, with the possibility of zooming the displayed image, then of translating the zoomed part in the screen 6; a closure of the image file, before you can select a second image to be viewed, again requiring to open the file of this second image, then close this file, to select a third image, et cetera. These operations of opening-editing image files quickly become embarrassing, even tedious, if the user of the terminal 1, 2 wants to quickly view a large number of images of a collection of images contained in a directory.

  According to FIGS. 2, 6 and 7, the method makes it possible, starting from the selection (step 20) in the collection of images 9 to N recorded in a directory stored in a memory of the server 3 or in a memory placed in the terminal 1, 2, to automatically create and display, in a step 30, at least one containing image 8. The containing image 8 contains a set of at least one selected image 9 to 17, according to the preceding step 20 step 30, from the initial image collection 9-N. The individual images 9-17 are grouped in the single image file of the containing image 8. In other words, the selected images 9-17 are preferably grouped in a single image: the image containing 8. The creation of the image container 8 comprising the set of at least one image 9-17 is operated by a compression of each of the images 9-17, and by cutting the image containing 8 tiles 9A 'to 17A' (Figure 7), to enable the contents of a compressed image 9-17 to be displayed in one of the tiles 9A 'to 17A' (or 9A'-17A ') of the containing image 8. The creation of the containing image 8 is performed on the terminal 1, 2, or on the server 3.

  To produce a containing image 8 with, for example, nine 9-17 images recorded in the form of as many tiles 9A'-17A ', it is possible to produce a file of JP2 type presenting a packaging of tiles or "codestream", which is complies with the JPEG 2000 part 1 standard (ISO 15444-1). The "codestream" is composed of a "main header", whose data are valid for the entire package, and a set of "tilestreams". The main header for example describes the number of available resolutions in the image, the size of the image and tiles. Each "tilestream" is dedicated to a tile, and consists of a header or "tile header", and compressed image data grouped into packets ("pack stream"). The header of each tile contains a specific marker named "Start Of Tile" (SOT), which contains, among other information, the index of the iT file. The present invention uses the index information contained in the marker to make the link between a request for enlargement on an individual image of the containing image, for example visually identifiable by a number superimposed graphically on the image, and the addressing the data in the physical file. Several "codestreams" can be juxtaposed in the same JP2 or JPX file; this means that a containing image file may contain, for example, several image albums that will, for example, classify the images by resolution. Files compressed with the JPEG2000 standard benefit from multiresolution, acquired by wavelet compression.

  In the compression process with JPEG 2000, a source image is decorrelated into components, and each component is cut into tiles. Then, dyadic transforms are applied to each of the tiles, to obtain different resolutions. Other operations are then applied, to obtain the final codestream, such as quantization and entropy coding. The multiresolution aspect is provided by the successive wavelet transforms. Starting for example from a file having a resolution 3000 by 2000 pixels, five successive transformations lead to the availability of the following six resolutions: 3000 by 2000, 1500 by 1000, 750 by 500, 375 by 250, 188 by 125, 94 by 62 The application responsible for displaying and decoding the images then chooses the most appropriate resolution according to the magnification requested by the client. Example of Creating and Updating a Container Image To create a JP2 containing image, consisting of nine regular tiles of 3000 pixels (horizontal resolution) per 2000 pixels (vertical resolution), the following 25 steps are performed: 1. creation of a containing image comprising only pixels of uniform color (white for example) and of size 9000 pixels (horizontal resolution) by 6000 pixels (vertical resolution), cut into regular tiles of 3000 by 2000 pixels (horizontal resolution by vertical resolution); 2. populating the different "tilestreams" of this image containing the source images according to the following substeps, applicable to each of the images to be integrated: a. possible addition of a frame around the image; b. resizing the image to the size of the tile so as to optimize the display according to the aspect ratio of the image and the host tile, i. if the image has a resolution greater than 90% of 3000 (2700) horizontally or 90% of 2000 (1800) vertically, decimate the image so that its largest dimension is 10% less than the corresponding dimension of the tile. For example, for an image of 4500 pixels (horizontal resolution) by 4500 pixels (vertical resolution), a final image of 1800 by 1800 pixels; for an image of 3600 by 2400 pixels, a final image of 2700 by 1800 pixels and for an image of 2000 by 3000 pixels, a final image of 1200 by 1800 pixels; ii. if the image is less than 90% of the tile size (2700 by 1800 pixels), stretch the image to maximize space occupancy. For example, for an image 900 pixels (horizontal resolution) per 600 pixels (vertical resolution), a final image of 2700 by 1800 pixels; for an image of 1000 by 1500 pixels, a final image of 1200 by 1800 pixels; vs. adding uniform edges around the edge of the image so as to obtain an image producing exactly 3000 pixels by 2000 pixels. This consists, for example, in adding 100 pixels at the top and bottom of the image, and 150 pixels to the right and left of the image for an image of 2700 by 1800 pixels; d. erasing the "tilestream" of the tile to be updated, and writing the new "tilestream" obtained after compression of the prepared image according to the substeps a, b, c; 3. In an optimized approach, the creation of the containing image is done by examining the resolution of each of the images to be embedded in the tiles, and the decision of the size of the containing image (and therefore of the tiles) is taken according to the maximum and minimum resolution of each of the original images to be incorporated, and the minimization of their degradation by decimation or stretching.

  In an advantageous embodiment of the invention, using a known standardized compression method, such as JPEG 2000 (Joint Photography Expert Group, ISO / IEC 15444 standard), the containing image 8 is cut out or subdivided into an integer number of tiles. . It is understood that this number is arbitrary, and that the containing image 8 can include any number of tiles. The preferred number of tiles 9A'-17A 'of the containing image 8 is new, as described in the example above, and as shown in Figures 2, 6, and 7. The number of tiles of the containing image 8 may be greater than or equal to the number of selected images 9-17 to be included in the containing image 8. If the number of zones of the containing image 8 is greater than the number of selected images 9-17, new images selected can be easily added in the tiles left uniform, preferentially white, of the image containing 8, until reaching the maximum number of available tiles of (s) the image (s) containing (s) 8. But the number of Tiles of the containing image 8 may also be smaller than the number of selected 9-17 images; in this case, several containing images 8 are created to contain all the selected images 9-17.

  Each tile of the containing image 8 contains the pixels of at least one image 9-17 displayed in a resolution which is typically a small resolution. These images 9-17 are displayed in the form of thumbnails, in the corresponding areas 9A'-17A 'of the image containing 8. The display of the images 9-17 according to the small resolution, allows an acceptable visualization for the user, that is to say such as the set of thumbnails 9-17, included in the image containing 8, are visible in their entirety, and such that the content (the scene of the image) can be recognized by the user on the screen of the terminal 1, 2. Several (small) display resolutions of the image 9-17 are possible, depending on the display capacity of the terminal 1, 2. As already described ci above, if the number of selected images 9-17 is large, and does not allow an acceptable visualization in a single image containing 8, this image containing 8, encoded in a single image, can be broken down into several images 8 containers that can be displayed successively on the screen 6. A first embodiment of the procedure é makes it possible to pass from the display of a first containing image to the display of a second containing image by closing, with the keyboard 7 of the terminal 1, the file of the first containing image, then opening the file of the second picture containing. A second advantageous embodiment of the method makes it possible to display successively and automatically, for example according to an adjustable delay, each of the containing images, without having to close and open respective files corresponding to these containing images.

  The method of the invention makes it possible to display, in the same image containing 8, images 9-17 which have different resolutions. That is, the packages of the tiles 9A'-1 7A 'are different in this same containing image. The algorithm of the method of the invention leads for example to integrate, in a first packaging of tiles, individual images of maximum resolution 4 megapixels, then, in a second packaging of tile, individual images of maximum resolution 2 megapixels, and finally, in a third tile package, individual images of maximum resolution 1 megapixel. Each of these packages is accessible, for example, with a tab displayed in the screen interface. This advantage of the method of the invention gives the possibility of integrating, into the same containing image 8, an arbitrary number of individual images 9-17, for example in the form of mini albums of images, each corresponding to a plurality of tiles.

  Another advantage of the invention is that the containing image 8 thus created can be modified or updated, that is to say that one or more individual images 9-17 can be added or removed in the image containing, without having to decompress and recompress all these individual images of the containing image. The operation of updating the image containing 8 is performed on the terminal 1 or on the server 3.

  The display of the containing image 8 is operated by opening a single image file; that is, if, for example, the user opens the encoding file of the containing image 8, and this containing image 8 contains for example sixteen images, whereas an acceptable visualization, taking into account of the characteristics of the terminal used, corresponds (as shown in FIG. 2) to the display of only nine zones on the screen, then a first containing image 8 is displayed presenting the first nine images, then, a second containing image 8 is sequentially displayed showing the remaining seven thumbnails. The display of the second containing image 8 is preferably performed automatically according to a preset display delay for each displayed containing image.

  FIGS. 2 and 7 represent a containing image 8 capable of receiving nine 9-17 images in nine corresponding tiles 9A'-17A 'of the containing image 8. But, if the initial selection of images to be displayed in full screen contains than seven images, the two remaining "white" tiles of the containing image 8 are preserved. These white tiles contribute very little to the total weight of the image file, because the encoding of a white image, that is to say composed of white pixels, represents only very few bytes. On the other hand, if the user wants to select an eighth image, the method automatically places this eighth image selected in a second time, in one of these two tiles of white pixels.

  Figures 3 and 6 show a selected image 10, in a specific area of the containing image 8, with the keyboard of the terminal. From the selection of the image 10 in the image containing 8, according to a step 40, the method allows the automatic display of the image 10 in full screen. FIG. 3 represents a full screen display, in an advantageous embodiment, such that all the pixels constituting the displayed image 10 do not fill the entirety, that is to say is distributed over substantially all (less than 100%) the surface of the screen 6. This means that the image 10 preferably fills 70% or more, of the surface of the screen 6. But full screen display also means that all the pixels of the image 10 can fill the entirety (100%) of the surface of the screen 6 (not shown).

  FIG. 3 shows the embodiment in which the user can see on his screen not only all the pixels of the selected image 10, but also a portion of the pixels composing at least one other image 9, 11 of all previously selected 9-17 images. The images 9, 11 belong to the containing image 8, and are for example arranged in the image 8 just before and just after the image 10. These images 9, 11 are not selected at first, but they can be, if after viewing the image 10, the user needs to view, for example, the image 9 or the image 11. In a preferred embodiment, a single click operated with the keyboard 7, either in the image 9 or in the image 11, to display in full screen this image 9, 11 selected in a second time. In another embodiment, the image selection can be operated by entering, with the keyboard 7, an alphanumeric code 9A, 9B. This alphanumeric code 9A, 9B corresponds, for example, to the rank of increasing positioning of the chosen selected image to be displayed, according to the order of the lines formed by the zones of the containing image 8. Preferentially, the alphanumeric code 9A, 9B is a whole number. According to FIG. 2, it is for example advantageously displayed inside or around the images 9-17 of the containing image 8.

  According to FIG. 4, the compression method used, for example JPEG 2000, makes it possible moreover to enlarge by zooming, with the keyboard 7 of the terminal, a part 10P of the selected image 10 displayed according to the second resolution. Several zoom levels can be operated, thus allowing several successive enlargements of the portion 10P of the selected image.

  According to FIG. 5, the compression method used, for example JPEG 2000, also makes it possible, by using the keyboard 7 of the terminal (for example a "joystick" button), to translate the zoomed image portion 10P so as to display another part 10P 'of the image 10 displayed according to the second resolution.

  The display of the part 10P 'only needs to decode a minimum of pixel data, namely those which did not appear in the previous image 10P.

Claims (4)

  A method for controlling the display of a digital image (10) selected from a collection of digital images (9-N), comprising the following steps: a) automatic creation of a composite image (8), called "image" container ", formed of individual images (9-17), the containing image (8) being subdivided into a plurality of substantially contiguous zones (9A'-17A '), called" tiles ", and each individual image (9- 17) respectively having a given size and location in the containing image (8) corresponding to a tile (9A'-17A '); b) automatically displaying the containing image (8) and activating each tile of the containing image as a pointer to the individual image data corresponding to said tile, and, in response to the selection by the user of the image one of the tiles (9A'-17A '), c) enlarged automatic display of the individual image (10) corresponding to the selected tile (10A').   The method of claim 1, wherein the dimensions and location of the individual image (9-17) in the containing image (8) are determined automatically.   The method of claim 1, wherein the size and location of the individual image (9-17) in the containing image (8) is determined by the user.   4 - The method of claim 1, wherein the containing image (8) comprises images (9-17) having different resolutions.   - The method of claim 1, wherein the containing image (8) is subdivided into nine tiles (9A'-17A ') corresponding to nine individual images (9-17) and selectable respectively by nine keys of a numeric keypad.   The method of claim 1, further comprising displaying a tile selection cursor, driven by bidirectional control.   7 - The method of claim 1, further comprising the enlarged display of a portion of at least one image corresponding to a tile adjacent to the selected tile.   The method according to claim 1, wherein the image corresponding to the selected tile is displayed with an enlargement such that one of its dimensions corresponds to a dimension of a display screen (6) of a terminal ( 1, 2) used for the implementation of the method.   9 - Process according to claim 1, wherein image data corresponding to the set of individual images (9-17) of a containing image (8) are included in the same digital file, and in which each tile points to a subset of data in the file.   The method of claim 9, wherein the image data of each tile is compressed data.   11 - Method according to claim 1, wherein the creation of the containing image (8) is performed in a server (3), from images transmitted remotely, to the server, from a terminal (1,2) ).   12 - Method according to claim 10, wherein the display of the containing image (8) is operated in the terminal (1, 2), from the image data to be displayed, transmitted from the server (3) .   13 - Terminal (1, 2) provided with control means (7) and display (6), and comprising software for implementing the method according to one of claims 1 to 12.