Method and system for generating an image

[0001] This invention relates generally to the field of electro-optical devices specifically to a method and system for generating an image. METHOD AND SYSTEM FOR GENERATING AN IMAGE BACKGROUND OF THE INVENTION An optical sensor typically generates image information representing a sensed image. The image information may be analyzed by one or more image processors to generate at least a portion of the sensed image. A known technique for processing the image information may be performed by calculating and processing a matrix. Processing a matrix according to the known teclmique, however, consumes processing power, which may affect the battery life of a portable device. Additionally, memory may be required to store matrix information for the processed matrix, which may impact the cost and size of portable optical devices. Consequently, known techniques for processing image information may be masatisfactory in certain situations. SUMMARY OF THE INVENTION In accordance with the present invention, disadvantages and problems associated with previous techniques for generating an image may be reduced or eliminated. [00041 According to one embodiment, generating an image includes receiving a light at sensors, where the light is associated with images. A previous matrix is determined, where the previous matrix includes image information associated with an image. For each sensor, a current image data set corresponding to a cun'ent image is generated and a current matrix is determined using the previous matrix and the current image data. The current matrix includes image information associated with the cun-ent image. A fusion matrix is computed according to the current matrix of each sensor, where the fusion matrix initiates generation of a fused image. 100051 Certain embodiments of the invention may provide one or more technical advantages. A techlxical advantage of one embodiment may be that matrix computations may be reduced, resulting in lower power consumption and less memory usage. Another technical advantage of one embodiment may be that by calculating only the changes in the image from frame to frame, more efficient proeessing is performed, resulting in higher speed and, therefore, better resolution. Yet another teclmical advantage of one embodiment may be that by using hardware architecture to perform the matrix calculations and image analysis, overhead processing capabilities of a microprocessor may be avoided, resulting in faster processing at lower clock speeds. Yet another technical advantage of one embodiment may be that by reducing power and memory consumption, an image generation device may be more effective as a portable unit, especially in remote areas where recharging batteries may be impractical. Certain embodiments of the invention may include none, sonle, or all of the above teclmical advantages. One or more other technical advantages may be readily apparent to one sldlled in the art from the figures, descriptions, and claims included herein. BRIEF DESCRIPTION OF THE DRAWINGS For a more complete understanding of the present invention and its features and advantages, reference is now made to the following description, taken in conjunction with the accompanying drawings, in which: FIGURE 1 is a block diagram of one embodiment of an image generation system that may be used in accordance with the present invention; FIGURE 2 is a block diagram of another embodiment of 10 an image generation system that may be used in accordance with the present invention; and FIGURE 3 is a flowchart demonstrating one embodiment of a method for generating art image that may be used in accordance with the present invention. DETAILED DESCRIPTION OF THE DRAWINGS Embodiments of the present invention and its advantages are best understood by referring to FIGURES 1 through 3 of the drawings, like numerals being used for like and corresponding parts of the various drawings. FIGURE 1 is a block diagram of one embodiment of an image generation system 10 that may be used in accordance with the present invention. In general, system 10 may generate an image by determining a plurality of matrices that may be fused together to generate an image. An image processor 20 includes a matrix generator 24 that generates a matrix for each image received at each sensor of system by detecting changes in the image from frame to frame, which may potentially reduce the processing worldoad of image processor In operation, a sensor stage 15 includes a plurality of sensors that receive light 12 associated with a plurality of images. Image processor 20 determines a matrix for the light received at each sensor. A fusion processor 30 fuses the matrices to compute a fusion matrix that may be used by a fused image generator 40 to initiate the generation of a fused image. According to the illustrated embodiment, system includes sensor stage 15, image processor 20, fusion processor 30, fused 25 image generator 40, and a display 50 coupled as shown in FIGURE 1. Sensor stage 15 includes a plurality of sensors S 1 ,..., Sn,..., Sp, where each sensor is operable to receive light 12. Sensor stage 15 may include any number of sensors SI,...,Sp that perfonrl any suitable sensing without departing from the scope of the invention. For example, sensor stage 15 may include three sensors, $ 1 , $ 2 , and $ 3 , each sensor sensing light 12 at different wavelengths, ) I, 9 2 , 9 3 . In that embodiment, system 10 may be used to generate a color image based on the information received at sensors $ 1 through $ 3 if each sensor filters light 12 of wavelengths corresponding to the colors red, blue, and green. Sensors S 1 ,...,Sp may comprise cameras, infrared receivers, image intensifier devices, or any other suitable light sensing device. Sensors Sz...Sp may also filter any range of wavelengths without departing from the scope of the invention, Sensor stage 15 analyzes the sensed light 12 to yield raw image data. According to the illustrated embodiment, each sensor Sn analyzes sensed light 12 according to its filtering characteristics and outputs 15 raw image data in, where n represents the correspo,nding sensor. For example, a first sensor $ 1 analyzes light 12 to generate raw image data i 1 , while a second sensor $ 2 analyzes light 12 to generate raw image data i 2 . Sensor Sn may generate raw image data i 1 in any suitable format, such as in analog or digital format, or in any other suitable format without departing from the scope of the invention. According to one embodiment, each sensor Sn generates raw image data in as a stream of bits, packetized and/or encapsulated data, binary or otherwise, or in any other suitable format and at any suitable rate. Image processor 20 analyzes the raw image data in received from sensor stage 15 to determine enhancements to the image and to prepare the image for fusion. According to the illustrated embodiment, image processor 20 includes an image data generator 22 and a matrix generator 24. hnage data generator 22 receives the raw image data in from sensor stage 15 and generates image information. The image information may be used by matrix generator 24 to generate a matrix for each sensed image. According to the illustrated enlbodiment, image data generator 22 generates image information In, where n represents the corresponding sensor. Image information In may include any data corresponding to the sensed image, such as raw data, functions, numbers, arrays, or any other suitable representation of image data. Image data In may be received at any port, buffer, cache, memory, storage area, or any other suitable module of image data generator 22 of image processor 20. In one embodiment, image information In may be buffered at a rate of a specific number of lines of data at a time, such as two lines of data per millisecond. Any other suitable buffering technique using any suitable rate may be used at image data generator 22 without departing from the scope of the invention. Matrix generator 24 determines a matrix Mn for each sensed image. The matrix Mn quantifies the image information using algorithms, operations, or functions that may be used to represent the image. Matrices M 1 ,...,Mp may perform the algorithms, operations, or functions using the corresponding image information Ii,...,Ip to completely describe the image sensed by the corresponding sensor S 1 ,...,Sp. Matrices M 1 , .... Mp may include, however, any other quantification or characterization of an image representation without departing from the scope of the invention. For example, matrix Mn may quantify key features of an image, and may include target identifiers describing portions of the image that are targets; functions, operations, or algorithms representing gradients or variances of the spatial frequencies of the image; histograms providing information about light and dark areas of the image; or any other suitable manner of describing features of an image that may be of interest. According to the illustrated embodiment, matrix generator 24 calculates a current matrix M where n represents the con'esponding sensor, and i represents the current image frame Fi. According to one embodiment, current matrix M is calculated by determining the changes in the image from frame to frame. For example, at frame Fi for the image sensed by sensor $ 1 , matrix generator 24 determines a current matrix M At a subsequent frame F 2 , matrix generator 24 determines the changes in the images between frame F 2 and frame F 2 by analyzing the current image information I 1 generated by sensor S mad extracting the changes between the analyzed current image information I 1 and the previous image characterized by a previous matrix M( t-0. Image processor 20 may compute a change in the image using image information L and matrices M 1 ,...,Mn. According to the illustrated embodiment, image processor 20 may calculate a change matrix AM,, indicating a change in the image according to the previous matrix M,( -1) and the current image information In. Using the change matrix AM,,, image processor 20 may approximate the current matrix M by adjusting the previous matrix M!'-1) according to the change matrix AM,,. Fusion processor 30 generates a fusion matrix representing an enhanced image. According to the illustrated embodiment, fusion matrix Mf may comprise a matrix comprising numbers, functions, operations, algorithms, or any other suitable representation of the fusion of a plurality of matrices. According to one embodiment, fusion processor 30 receives and analyzes cmTent matrices M[ ..... M to determine image enhancements that nlay be performed to the image before displaying the image. Fusion, processor 30 may use any suitable fusion technique to generate fusion matrix My without departing from the scope of the invention. Fused image generator 40 may process fusion matrix Mf and generate a display matrix 45. Display matrix 45 uses the fusion matrix My and the current image information I¢, ...,/,,, to initiate the generation of a fused image at display 50. According to the illustrated embodiment, fused image generator 40 implements the approximations of the current matrices M[ ..... M fused at matrix Mf using the image information 1 1, ...,In, to generate a display matrix According to one embodiment, fused hnage generator 40 may generate display matrix 45, any fused image, or data representing an image for displaying at display 50 so that a human eye can perceive an image that at least in part represents at least a portion of the image associated with light 12. For example, fused image generator may initiate the generation of the image by processing display matrix 45 so that at least thirty frames per second are displayed at display 50. Any other suitable rate of processing may be used at fused image generator 40 without departing from the scope of the invention. For example, fused image generator 40 may process display matrix 45 at the rate of sixty frames per second. Display 50 may include any output device suitable for displaying an image. According to one embodiment, display 50 may comprise a monitor, a screen, a projection surface, an x-ray tube, an anode screen, or a liquid crystal display (LCD), or any other device suitable for displaying an image. [00261 Modifications, additions, or omissions may be made to system without departing from the scope of the invention. For example, image processor may be implemented using separate processors for the function of generating a matrix and the function of generating the image information. As another exmnple, fused image generator 40 and display 50 may be modified so that display 50 comprises a processor or other logic operable to perform the functions of fused image generator 40. As used in this document, "each" refers to each member of a set or each member of a subset of a set. Additionally, functions may be performed using any suitable logic comprising hardware, software, other logic, or any other suitable combination of the preceding. For example, although the term "processor" has been used to describe image processor 20, fusion processor 30, and fused image generator 40, any logic architecture may be used to perform the specific functions of each processor. According to the illustrated embodiment, image processor 20, fusion processor 30, and fused image generator 40 may comprise a field programmable gate array (FPGA), a neural net, logic operators, hardware architecture, solid state circuits, other real time gate devices, or any other suitable device that may be used to process the specific functions of image processor 20, fusion processor 30, and/or fused image generator 40. Any suitable nttmber of logic devices may be used to perform the functions of the processors at system 10. For example, system 10 may employ hundreds or thousands of gates to generate an image using the functions performed by the processors at system Accordingly, system 10 may generate an image using any hardware suitable for processing image information 1 1 in, matrices MI_M fusion matrix My, and display matrix 45. 100281 A known technique for processing the image information may be performed by calculating and processing a matrix for each frmrie of the sensed image. Processing a matrix for each frame, however, consumes processing power, which may affect the battery life of a portable device. Additionally, memory may be required to store matrix information for the entire processed matrix, which may impact the cost and size of portable optical devices, system 10 may provide an advantage over the known technique. Basing the architecture of system 10 on the above-mentioned hardware avoids the use of microprocessors, which may result in lower consumption of memory capacity and power. Reducing or eliminating the memory capacity used may also increase the processing speed at which system 10 generates an image, while maintaining power consumption to a minimum. FIGURE 2 is a block diagram of another embodiment of an image generation system 10 that may be used in accordance with the present invention. According to the illustrated embodiment, the system 10 illustrated at FIGURE 2 includes an enhancement processor 35 that is coupled to image processor 20 and fused image generator 40 as shown. Sensor 16 as illustrated is part of sensor stage 15 described with reference to FIGURE 1. Similarly, image processor 20, fusion processor 30, and fused image generator 40 are configured and operate as described with reference to FIGURE 1. Enhancement processor 35 may operate to enhance and condition components of matrices M 1 ..... M,, to generate enhanced image information Ie. Enhancement processor 35 may process the enhancements prior to and separately from fusing the matrices at fusion processor 30. For example, enhancement processor 35 may receive matrix M 1 and image information /i to condition, enhance, or initiate the conditioning or enhancement of the image data represented by the image information I 1 and matrix M 1 . [00311 Additional enhancement processors 35 may be added to one or more image paths of system 10. For example, an additional enhancement processor 35 may he added at the image path from a sensor $ 2 (not showal) so that image information/ 2 and matrix M may be processed in parallel to the processing of the image information/ 1 and matrix M 1 corresponding to sensor $ 1 . Any suitable number of enhancement processors may be added at system 10 without departing from the scope of the invention. Additionally, although the enhancement processing of the images has been described as occurring in parallel, any processing timing may be used by enhancement processor to produce elthanced image Ie. By enhancing an image at enhancement processor 35, fusion processor may fuse the matrices M 1 ,...,Mn without performing enhancement of the image content. Separating the functions of enhancement and fusion may result in a more versatile circuit capable of enhancing the image prior to fusing the matrices, or otherwise, as long as enhanced image information Ie and fusion matrix My are received in parallel at the fused image generator Additionally, the image information/ 1 ..... / and the matrices M 1 ..... M may be processed at a higher speed, which may be used if a high image resolution is desired. For example, enhancement processor 35 may be used to improve the quality of the fused image 55 if a display resolution of 1280x960 and higher is desired. Enhancement processor 35 may be used, however, regardless of the desired resolution. For example, enhancement processor 35 may be used to produce a resolution of 640x480 at a VGA display or any other suitable display. Modifications, additions, or omissions may be made to system without departing from the scope of the invention. For example, enhancement processor may be included at image processor 20 to ensure that enhancement of an image is performed prior to fusing the images at fusion processor 30. As yet another example, a display 50 may be added at system 10 of FIGURE 2 so that fused image 55 may be displayed. Additionally, functions may he performed using any suitable logic comprising software, hardware, other logic, or any suitable combination of the preceding. For example, as was described with reference to FIGURE 1, enhancement processor 35, although described as a processor, may be configured using the hardware logic described with reference to the processors of FIGURE 1. Enhancement processor may, however, be configured differently from the image processor 20, fusion processor 30, and fused image generator 40 described with reference to FIGURE 1. [00361 FIGURE 3 is a flowchart demonstrating one embodiment of a method for generating an image that may be used in accordance with the present invention.. The method begins at step 60 where sensors St ..... Sn at sensor stage 15 receive light 12. According to the illustrated embodiment, at least two sensors may be used at sensor stage for system 10 to generate at least two representations of an image associated with light 12. The method proceeds to step 62, where matrix generator 24 establishes a previous matrix. According to the illustrated embodiment, a previous matrix, may be established using the image information that may be received from image data generator 22 and/or sensor stage 15. Any other initialization matrix may be used by matrix generator 24 to establish a previous matrix without departing from the scope of the invention. At step 64, image data generator 22 generates current image data associated with a current frame received at a sensor. For example, image data generator 22 may generate image information I associated with a frame £' 1 received at sensor $ 1 . Matrix generator 24 calculates a change matrix according to the previous matrix and the current image data at step 66. As was described with reference to FIGURE 1, a change matrix AM,, representing the changes in the image may be used to calculate a current matrix M and may be calculated by extracting the differences between the current image data In, and the previous matrix M! -1). The change matrix AM,, may he calculated according to Equation (1): vs,, = z,, - M,!'-1) Matrix generator 24 calculates a current matrix according to the previous matrix and the change matrix, at step 68. A current matrix M may be described by Equation (2): As was described with reference to FIGURE 1, a matrix M for the current frame i may be calculated by analyzing the image information I 1 to determine how to condition the image so that enhancements may be performed to the previous matrix. According to one embodiment, matrix generator 24 analyzes image information / by extracting functions that may be performed on the image data to condition image characteristics such, as spurious portions of an image, weak portions of an image, contrast aspects of an image, brightness, sharpening, dulling, or any other suitable image characteristic suitable for enhancement by image processor At step 70 the method determines if a next sensor is available at system 10. If there is a next sensor, the method returns to step 64, where the image data generator 22 of image processor 20 generates a current image data I associated with a cmTent frame received at the next sensor $ 2 . '[0042] If there is no next sensor at step 70, the method proceeds to step 72, where fusion processor 30 computes a fusion matrix Mf according to the current matrices M[ ..... M According to one embodiment, the fusion matrix Mf may be generated by fusing at least two ruffing frames of data included in current matrices M[ ..... M Enhancement processor 35 may enhance the current image data associated with the received frame at step 74. For example, as was described with reference to FIGURE 2, enhancement processor 35 may enhance, condition, or initiate the conditioning or enhancement of the image data to produce enhanced image information Ie. At step 76, fused image generator 40 generates a fused image 55 using the fusion matrix Mr. According to one embodiment, fused image generator 40 may receive enhanced image Ie and fusion matrix Mfto generate a display matrix 45 that may be used to generate fused image 55. According to another embodiment, fused image generator 40 may receive fused matrix My and image information I 1 .... ,In to generate a display matrix 45. Fused image generator 40 generates display matrix 45 using the functions included in fused matrix My applied to the image information/ 1 , ...,/ . [00451 Image processor 20 updates the previous image matrix with the current image matrix at step 78. The method determines if there are next frames to be processed at step 80. If there are frames to be processed, the method returns to step 74 to generate a current image data associated with a current frame received at a sensor. If there are no next fi'ames to process, the method terminates. Modifications, additions, or omissions may be mad to the method without departing from the scope of the invention. For example, enhancing the current image data associated with a received frame at step 74 may be omitted if an enhancement processor 35 is not used at system 10. As another example, a step may be added after enhancing the current image data at step 74, where a display matrix 45 is generated at fused image generator 40. Additionally, steps may be performed in any suitable order without departing from the scope of the invention. For example, calculating a current matrix according to the previous matrix and the current image data at step 66 may be performed substantially simultaneously. As another example, determining if a next sensor is to be processed at step 70 may be omitted so that the steps of generating a current image data at step 64, calculating a current matrix at step 66, and calculating a change matrix at step 68 are performed substantially in parallel for each sensor S,, at sensor stage 15. As yet another example, computing a fusion matrix according to the current matrices at step 72 may be performed substantially simultaneously with enhancing the current image data associated with a received frame at step 74. Certain embodiments of the invention may provide one or more technical advantages. A technical advantage of one embodiment may be that matrix computations may be reduced, resulting in lower power consumption and less memory usage. Another technical advantage of one embodiment may be that by calculating only the changes in the image from frame to frame, more efficient processing is performed, resulting in higher speed mad, therefore, better resolution. Yet another technical advantage of one embodiment may be that by using hardware architecture to perform the matrix calculations and image analysis, overhead processing capabilities of a microprocessor may be avoided, resulting in faster processing at lower clock speeds. Yet another technical advantage of one embodiment may he that by reducing power and memory consumption, an image generation device may be more effective as a portable unit, especially in remote areas where recharging batteries may be impractical. Although an embodiment of the invention and its advantages are described in detail, a person skilled in the art could make various alterations, additions, and omissions without departing from the spirit and scope of the present invention as defined by the appended claims. Throughout this specification and the claims, unless the context requires otherwise, the word "comprise" and its variations, such as "comprises" and "comprising," will be understood to imply the inclusion of a stated integer or step or group of integers or steps but not the exclusion of any other integer or step or group of integers or steps. The reference to any prior art in this specification is not, and should not be taken as an acknowledgement or any form of suggestion that such art forms part of the common general knowledge in Australia.