초록 ▼

The invention relates to the field of methods for zooming onto a part of an image which consists of pixels and which represents a terrain overflown by an aircraft. It is a zoom method for zooming onto a part of an image which consists of pixels and which represents a terrain overflown by an aircraft

The invention relates to the field of methods for zooming onto a part of an image which consists of pixels and which represents a terrain overflown by an aircraft. It is a zoom method for zooming onto a part of an image which consists of pixels and which represents a terrain overflown by an aircraft, an image being modulated, pixel by pixel, by a shading cue representative of the relief of a terrain. The shading cue is determined by way of a computation carried out, in a reference frame of a display screen of an aircraft, pixel by pixel, on the basis of the altitudes of pixels neighboring the current pixel in the case of the unzoomed image. The method according to the invention can in particular be implemented in a cartographic accelerator card.

대표청구항 ▼

The invention claimed is: 1. A zoom method for zooming onto a part of an image which includes pixels and which represents a terrain overflown by an aircraft comprising the steps of: modulating an image, pixel by pixel, by a shading cue representative of the relief of a terrain, determining said sha

The invention claimed is: 1. A zoom method for zooming onto a part of an image which includes pixels and which represents a terrain overflown by an aircraft comprising the steps of: modulating an image, pixel by pixel, by a shading cue representative of the relief of a terrain, determining said shading cue being by way of a computation carried out, in a reference frame of a display screen of an aircraft, pixel by pixel, on the basis of a altitudes of pixels neighboring the current pixel in the case of the unzoomed image, characterized in that, in the case of an image zoomed with a zoom factor whose value belongs to a given span distinct from the span to which a unit zoom factor belongs, the latter corresponding to an unzoomed image, the shading cue is determined by way of said computation carried out on the basis of the altitudes of pixels which are more remote from the current pixel than the neighboring pixels, by a remoteness factor whose value belongs to said given span. 2. The zoom method as claimed in claim 1, wherein the computation determines the shading cue on the basis of four pixels forming the vertices of a square whose current pixel is the center, the shading cue being obtained on the basis of the difference in altitude between the pixel situated at the top left of the current pixel and the pixel situated at the bottom right of the current pixel and of the difference in altitude between the pixel situated at the top right of the current pixel and the pixel situated at the bottom left of the current pixel. 3. The zoom method as claimed in claim 2, wherein a saturation function is applied to the result of each difference. 4. The zoom method as claimed in claim 1, wherein the shading cue is obtained directly by reading a lookup table with two inputs, one of the inputs receiving the difference in altitude between the pixel situated at the top left of the current pixel and the pixel situated at the bottom right of the current pixel and the other input receiving the difference in altitude between the pixel situated at the top right of the current pixel and the pixel situated at the bottom left of the current pixel. 5. The zoom method as claimed in claim 4, wherein the values of the table are recomputed with each change of scale of an image and with each change of the zoom. 6. The zoom method as claimed in claim 1, wherein the number of bits for coding the altitude differences is less than the number of bits for coding the altitudes, and in that the correspondence between the bits for coding the altitude differences and the bits for coding the altitudes is variable so as to accommodate the variation in the altitude differences as a function of the variation in the remoteness of the pixels entering into the computation of said altitude differences. 7. The zoom method as claimed in claim 6, wherein the value of the scale of an image decreases substantially, the weight of the bit for coding the altitudes corresponding to the least significant bit of the coding of the altitude differences increases. 8. The zoom method as claimed in claim 6, wherein the value of the zoom increases substantially, the weight of the bit for coding the altitudes corresponding to the least significant bit of the coding of the altitude differences decreases. 9. The zoom method as claimed in claim 2, wherein the zoom method uses the abutting succession of four queue stacks of specified lengths in such a way that the altitude of the pixel situated at the bottom right of the current pixel is available at the level of the input of the first queue stack, the altitude of the pixel situated at the bottom left of the current pixel is available between the output of the first queue stack and the input of the second queue stack, the altitude of the current pixel is available between the output of the second queue stack and the input of the third queue stack, the altitude of the pixel situated at the top right of the current pixel is available between the output of the third queue stack and the input of the fourth and last queue stack, the altitude of the pixel situated at the top left of the current pixel is available at the level of the output of the fourth and last queue stack. 10. A cartographic accelerator card, comprising: modulation means for modulating an image, pixel by pixel, by a shading cue representative of the relief of a terrain, means for determining said shading cue being by way of computing, in a reference frame of a display screen of an aircraft, pixel by pixel, on the basis of a altitudes of pixels neighboring the current pixel in the case of the unzoomed image, characterized in that, in the case of an image zoomed with a zoom factor whose value belongs to a given span distinct from the span to which a unit zoom factor belongs, the latter corresponding to an unzoomed image, the shading cue is determined by way of said computation carried out on the basis of the altitudes of pixels which are more remote from the current pixel than the neighboring pixels, by a remoteness factor whose value belongs to said given span. 11. The cartographic accelerator card as claimed in claim 10, wherein said determining means determines the shading cue on the basis of four pixels forming the vertices of a square whose current pixel is the center, the shading cue being obtained on the basis of the difference in altitude between the pixel situated at the top left of the current pixel and the pixel situated at the bottom right of the current pixel and of the difference in altitude between the pixel situated at the top right of the current pixel and the pixel situated at the bottom left of the current pixel. 12. The cartographic accelerator card as claimed in claim 11, wherein a saturation function is applied to the result of each difference. 13. The cartographic accelerator card as claimed in claim 11, wherein the shading cue is obtained directly by reading a lookup table with two inputs, one of the inputs receiving the difference in altitude between the pixel situated at the top left of the current pixel and the pixel situated at the bottom right of the current pixel and the other input receiving the difference in altitude between the pixel situated at the top right of the current pixel and the pixel situated at the bottom left of the current pixel. 14. The cartographic accelerator card as claimed in claim 13, wherein the values of the table are recomputed with each change of scale of an image and with each change of the zoom. 15. The cartographic accelerator card as claimed in claim 11, wherein the number of bits for coding the altitude differences is less than the number of bits for coding the altitudes, and in that the correspondence between the bits for coding the altitude differences and the bits for coding the altitudes is variable so as to accommodate the variation in the altitude differences as a function of the variation in the remoteness of the pixels entering into the computation of said altitude differences. 16. The cartographic accelerator card as claimed in claim 15, wherein the value of the scale of an image decreases substantially, the weight of the bit for coding the altitudes corresponding to the least significant bit of the coding of the altitude differences increases. 17. The cartographic accelerator card as claimed in claim 15, wherein the value of the zoom increases substantially, the weight of the bit for coding the altitudes corresponding to the least significant bit of the coding of the altitude differences decreases. 18. The cartographic accelerator card as claimed in claim 11, wherein the zoom method uses the abutting succession of four queue stacks of specified lengths in such a way that the altitude of the pixel situated at the bottom right of the current pixel is available at the level of the input of the first queue stack, the altitude of the pixel situated at the bottom left of the current pixel is available between the output of the first queue stack and the input of the second queue stack, the altitude of the current pixel is available between the output of the second queue stack and the input of the third queue stack, the altitude of the pixel situated at the top right of the current pixel is available between the output of the third queue stack and the input of the fourth and last queue stack, the altitude of the pixel situated at the top left of the current pixel is available at the level of the output of the fourth and last queue stack.