Patent Publication Number: US-7583294-B2

Title: Face detecting camera and method

Description:
CROSS-REFERENCE TO RELATED APPLICATION(S) 
   This is a continuation of application Ser. No. 09/514,436, filed Feb. 28, 2000 now U.S. Pat. No. 6,940,545. 

   FIELD OF THE INVENTION 
   The present invention is in the field of image capture, and in particular in the field of image processing for the purpose of enhancing and optimizing the process of image capture by a camera. 
   BACKGROUND OF THE INVENTION 
   A preponderance of images collected by photographers contain people, which are often the most important subjects of the images. Knowledge of the presence and location of people in an image, and especially the presence and location of their faces, could enable many beneficial improvements to be made in the image capture process. Some are suggested in the prior art. For example, automatic and semi-automatic focusing cameras often pick a portion of the scene on which to adjust for best focus. If the camera could locate the faces in a scene, then focus could be optimized for the faces unless the photographer explicitly overrides that choice. In U.S. Pat. No. 5,835,616 a face detection system is used in automated photography to eliminate manual adjustment problems that can result in poor quality from lack of focused subjects. 
   Furthermore, detection of the faces in a scene gives very strong evidence of the proper location of the principal subject matter. In that connection, the process disclosed in the &#39;616 patent automatically finds a human face in a digitized image taken by a digital camera, confirms the existence of the face by examining facial features and then has the camera automatically center itself on the detected face. Detection of a face also yields strong evidence of proper color balance for the facial and/or skin area. For example, in U.S. Pat. No. 5,430,809 a video camera autonomously tracks a facial target in order to set a measuring frame on the facial object for purpose of auto exposure and auto focus. In addition, once the measuring frame is set, an auto white balance system adjusts colors to obtain optimal skin color on the face. As a result, the auto white balance system is said to perform auto skin color balance. It is also known (from U.S. Pat. No. 5,629,752) to detect a human face and then to utilize data representing color and/or density of the facial region to determine an exposure amount such that the region corresponding to the face can be printed appropriately by a photographic printer. 
   While face detection has been studied over the past several years in relation to the subject of image understanding, it remains an area with impressive computational requirements, particularly if a robust face detection algorithm is needed. A number of methods have been devised that show reasonable performance over a range of imaging conditions. Such methods may be more successfully implemented in large scale processing equipment, such as photographic printers, which have relatively sophisticated processing capability (compared to a hand-held camera). The challenge is to implement these face detection methods reasonably in a camera with limited memory resources, and with low computational cost. If this can be done successfully, the detection of faces in a scene will then serve as a springboard to numerous other improvements in the image capture process. In addition, it would be useful to detect faces in order to implement downstream activities after image capture, e.g., face detection could provide evidence of up/down orientation for subsequent printing (for example, of index prints). 
   SUMMARY OF THE INVENTION 
   It is an object of the invention to capture images and detect one or more of the human faces contained in the images, for the purposes of adding value to the image capture process and improving quality in the captured image. 
   The present invention is directed to overcoming one or more of the problems set forth above. Briefly summarized, according to one aspect of the present invention, a method is provided for determining the presence of a face from image data. The method comprises the steps of: 
   (a) prescreening the image data with a first algorithm, the first algorithm determining a plurality of face candidates utilizing a pattern matching technique that identifies image windows likely to contain faces based on color and shape information; and 
   (b) operating on the face candidates with a second algorithm, the second algorithm processing the face candidates using a posterior probability function classifier to determine the presence of the face. 
   In an illustrative embodiment, the first algorithm has a first rate of false positives, and the second algorithm has a second rate of false positives lower than the first rate of false positives. 
   Another aspect of the invention relates to a digital camera for implementing the above-described method. Such a digital camera may comprise, for example, a capture section for capturing an image and producing the image data; an electronic processing section for processing the image data to determine the presence of one or more faces in the image; face data means associated with the processing section for generating face data corresponding to at least one attribute of at least one of the faces in the image; a storage medium for storing the image data; and recording means associated with the processing section for recording the face data with the image data on the storage medium. 
   An advantage of one or more of the above aspects is that a digital camera can be configured to use the face detection capability to improve the picture taking experience for the user, as well as to provide numerous suggestions to obtain better and more pleasing photographs. 
   These and other aspects, objects, features and advantages of the present invention will be more clearly understood and appreciated from a review of the following detailed description of the preferred embodiments and appended claims, and by reference to the accompanying drawings. 

   
     BRIEF DESCRIPTION OF THE DRAWINGS 
       FIG. 1  is a block diagram of a face detecting camera showing an arrangement of camera elements in accordance with the invention. 
       FIG. 2  is a block diagram of the image capture section of the camera shown in  FIG. 1 . 
       FIG. 3  is a flowchart diagram of camera operations involved in the operation of the camera shown in  FIG. 1  in a framing image mode. 
       FIG. 4  is a flowchart diagram of camera operations involved in the operation of the camera shown in  FIG. 1  in a final image mode. 
       FIG. 5  is a flowchart showing the generation of composition suggestions. 
       FIG. 6  is an illustration of an image area divided into a grid for application of the rule of thirds. 
       FIGS. 7A-7D  are examples of the shape models for frontal and right semi-frontal poses used in one of the face detection algorithms. 
       FIGS. 8A and 8B  show graphical displays of probability densities for skin, which are used in one of the face detection algorithms. 
       FIGS. 9A and 9B  show graphical displays of probability densities for hair, which are used in one of the face detection algorithms. 
       FIGS. 10A-10C  show an original image and its reconstruction following principal component analysis in accordance one of the face detection algorithms. 
   

   DETAILED DESCRIPTION OF THE INVENTION 
   Because imaging systems employing electronic and film capture are well known, the present description will be directed in particular to attributes forming part of, or cooperating more directly with, systems and apparatus in accordance with the present invention. System attributes and component apparatus not specifically shown or described herein may be selected from those known in the art. In the following description, a preferred embodiment of the face detection algorithm would ordinarily be implemented as a software program, although those skilled in the art will readily recognize that the equivalent of such software may also be constructed in hardware. Given the system and methodology as described in the following materials, all such software implementation needed for practice of the invention is conventional and within the ordinary skill in such arts. If the face detection aspect of the invention is implemented as a computer program, the program may be stored in conventional computer readable storage medium, which may comprise, for example; magnetic storage media such as a magnetic disk (such as a floppy disk) or magnetic tape; optical storage media such as an optical disc, optical tape, or machine readable bar code; solid state electronic storage devices such as random access memory (RAM), or read only memory (ROM); or any other physical device or medium employed to store a computer program. 
   Referring now to the block diagrams of  FIGS. 1 and 2 , a camera  10  is shown as an integrated system embodying the components of a standard camera, including an image capture section  20 , a processor or central processing unit (CPU)  30 , a digital memory  32  for storing captured images and associated annotations related to the images, and a display device  34  for displaying captured images and/or other data useful in operation of the camera. The capture section  20  includes an optical section  21  having autofocus capability for focusing an image  22  (including, for purposes of this description, one or more faces) upon an image sensor  23 , such as a conventional charge-coupled device (CCD). An exposure control mechanism  24  includes an aperture and shutter for regulating the exposure of the image upon the image sensor  23 . Instead of (or in addition to) an electronic capture device, the capture section may include an analog storage device  25 , such as a conventional photographic film. In the case of well-known APS film, which includes a magnetic recording layer, a recording device  26  can record annotation data regarding the captured images on the magnetic layer. A flash unit  27  is also provided for illuminating the image  22  when ambient light is insufficient. 
   The CPU  30  is interconnected via a system bus  40  to a random access memory (RAM)  42 , a read-only memory (ROM)  44 , an input/output (I/O) adapter  46  (for connecting the capture section  20 , the digital memory  32 , the recording unit  26  and the flash  27  to the bus  40 ), a communication adapter  48  (for connecting directly to an information handling system or a data processing network, such as the Internet), a target tracking stage  49  (for generating a measuring frame  49   a  that tracks the faces), a user interface adapter  50  (for connecting user interface devices such as a shutter button  52 , flash controls  54 , programmed exposure selections  56 , a user manipulated display cursor  58  and/or other user interface devices to the bus  40 ), a algorithm interface adapter  60  (for connecting various stored algorithms to the bus  40 , including a face detection algorithm  90 ) and a display interface  70  (for connecting the bus  40  to the display device  34 ). The CPU  30  is sufficiently powerful and has sufficient attached memory  42  and  44  to perform the face detection algorithm  90 . A training database  72 , connected to the bus  40 , contains sufficient training data to enable the face detection algorithm  90  to work for a very wide range of imaging conditions. In the preferred embodiment, as will be described in detail, the face detection algorithm includes two component algorithms: a first component algorithm that estimates a face candidate region of the image based on a comparison between facial shape models and facial probabilities assigned to image pixels within the region and a second component algorithm operative on the face candidate region using pattern analysis to examine each region of the image and thereby confirm a facial presence in the region. The advantage of this combination is that the first component algorithm can be designed to operate quickly albeit with the potential for false positives and the second component algorithm can restrict its more computationally intensive processing to the relatively few regions that have passed the first algorithm. 
   The results of face detection are used to control a number of functions of the camera, which are embodied in the algorithms connected to the data bus  40  through the interface adapter  60 . The face detection results are tracked by the target tracking stage  49 , which sets and manipulates the measuring frame  49   a  to track, e.g., the centroid of one or more face locations. The measuring frame is used as described in U.S. Pat. No. 5,430,809, which is incorporated by reference, to limit the data collected for purposes of autofocus, auto exposure, auto color balance and auto white balance to the facial areas. The measuring frame may be a small spot-like area or it may be configured to have borders generally coinciding with the borders of one or more faces; in either case it is intended to confine the data collected for the algorithms to face data or some sample thereof. These algorithms include a red eye correction algorithm  80 , an exposure control algorithm  82 , a flash control algorithm  84 , a focus control algorithm  86 , a color balance algorithm  88  and a composition algorithm  92 . The red eye correction algorithm  80  adjusts the stored digital pixel values to remove a red eye condition produced by the flash unit  27 . The exposure control algorithm  82  determines settings from the measuring frame  49   a  for the image exposure control mechanism  24  in the image capture section  20  of the camera so that the faces are properly exposed. In conjunction with the exposure control determination, the flash algorithm  84  determines whether or not to fire the flash for optimal capture of the facial images. The camera utilizes the focus algorithm  86  to derive distance data from the measuring frame  49   a  and to set a pointable focus mechanism in the optical section  21  using the results of a framing image so that a final captured image is properly focused on the face regions. The color balance algorithm  88  is applied to the digital image file in order to optimize the representation of the skin regions within the measuring frame  49   a  so that they match the expected color range of skin tones. 
   The image display device  34  enables a photographer to preview an image before capture and/or to view the last image captured. In addition, an optical viewfinder  28  is provided for previewing an image. Moreover, the CPU  30  may employ the face detection algorithm to highlight faces within the viewed image if needed. For this purpose, a semi-transparent liquid crystal display (LCD) overlay  29  may be provided in the optical viewfinder  28 ; an LCD driver  29   a  activates certain areas of the LCD overlay  29  corresponding to one or more face locations in response to face location data from the CPU  30  (such an LCD mask is disclosed in U.S. Pat. No. 5,103,254, which is incorporated herein by reference). Also, the CPU  30  can generate highlighted or outlined faces by driving the pattern generator  74  via the display interface  70  to display, e.g., a box over a face in a viewing area shown on the display device  34 . Furthermore, the faces can be marked by a photographer by moving the cursor  58  on the viewing area of the display device  34  so that, e.g., it overlies a face or it draws a box around a face. This could also be done through the LCD driver  29   a  and the LCD overlay  29  in the optical viewfinder  28 . 
   Another advantage of the present invention is that data associated with the detection of faces in an image could be automatically recorded and included with or as an annotation of an image. This permits the automatic recording of significant subjects within a photographic record of events without requiring the annotation to be done by the photographer at the time of image acquisition or at a later time. The detection of faces in the scene then opens the way for significant additional enhancements to the image capture event and to subsequent processing of the image. For example, face detection will provide a convenient means of indexing images for later retrieval, for example by fetching images containing one or more people as subjects. Consequently, running the face detection algorithm provides face data corresponding to one or more parameters such as location, orientation, scale and pose of one or more of the detected faces. In addition, once faces have been detected, a simple face recognition algorithm can be applied to identify faces from a small gallery of training faces that the camera has previously captured with help from the user and stored in a training data base. The results of face detection and location are stored in an auxiliary data location attached to the image, which are together stored in buffer memory in the RAM  42 . Images are annotated, for example, with the coordinates of detected faces, estimates of face size, positions of the eyes, a rough estimate of the pose parameters of the head, and the identity of each individual. Once an image is selected for storage, the image and its annotation data can either be stored together in the digital image memory  32  or the annotations can be stored in the magnetic layer of the analogue image memory  25  (the image would be stored as a conventional latent image on the photographic emulsion). In one configuration for a digital camera, the captured image data is recorded in the storage medium in digital folders dedicated to images with a particular number of faces in the scenes. 
   It should also be understood that a further embodiment of the invention is a hybrid camera which simultaneously captures an image of a scene on both an electronic medium, such as the image sensor  23 , and a film medium, such as the APS film  25 . In this embodiment, the CPU  30  processes the image data from the image sensor  23  to determine the presence of one or more faces in the scene, and face data is generated corresponding to the location, scale or pose of at least one of the faces in the image. Such face data could be displayed to the user of the camera on the display  34  in order to evaluate the captured image. If the face data (or image) would suggest a problem with the captured image, the user would have the opportunity to recapture the image on another frame of the film  25 . Additionally, the face data could be written on the magnetic layer of the film medium  25  by activation of the recording unit  26 . 
   As shown in the diagrams of  FIGS. 3 and 4 , respectively, the camera operates first in a framing mode and then in a final imaging mode. In each mode, the camera offers a number of automated features to assist the photographer. The photographer has the option of disabling the framing mode through the user interface adapter  50 , thereby disabling acquisition of the framing image and going directly to the final imaging mode. 
   Framing Mode 
   In the framing mode shown in  FIG. 3 , the camera  10  obtains a framing image in step  100  by activation of the capture section  20 . The CPU  30  then performs the face detection algorithm  90  in step  120 , by which it attempts to detect any faces in the framing image and indicate their locations to the photographer in the viewfinder  28  or on the display device  34 . More specifically, the face detection algorithm utilizes face training data from the training database  72  to find faces. If faces are detected in the decision block  130 , then face location data is stored in step  140  in the RAM  42  for subsequent utilization by one or more of the camera algorithms. Furthermore, the facial locations are processed by the display interface  70  and, e.g., the faces produced on the display device  34  are outlined with a box or some other kind of outlining feature. If the face detection algorithm  90  is unable to find any faces, this fact is reflected in the outcome of the decision block  130 . Thus, in response to a face detection failure, i.e., when no faces are found, the photographer can return to the beginning via path  132  and slightly repose the scene and allow another chance at detection, or can choose in a manual decision block  134  to provide manual detection input to the camera using the cursor  58  to manually locate a face in the viewfinder  28  or on the display  34 . Other input techniques can be used, for example, a touch sensitive screen and stylus (not shown). Then, armed with knowledge of face presence and face location in the framing image, the camera  10  is able to provide valuable services to the photographer that can be used to improve the final captured image. Such services include focus assistance, exposure and flash determination and composition aids, as follows. 
   Focus assistance. Many modern cameras provide automatic focusing or user-designated focusing using a focusing aim point in the view finder. Since people, when they appear, are usually the most important subject in images, it is reasonable to properly focus the image on the faces of people unless directed otherwise by the photographer. Systems are presently known (see, e.g., U.S. Pat. No. 5,749,000, which is incorporated herein by reference) which include multiple focus detection areas and a steerable selection mechanism which selects one of the areas in response to an input stimulus (such as a voice instruction). Alternatively, as shown in the aforementioned &#39;809 patent, autofocus can be performed within a measuring frame that is set to include a face. In connection with the present invention, after performing face detection on the framing image, the camera  10  engages the focus control algorithm  86  in a focus step  150  to use its steerable auto-focusing system in the optical section  21  to select a particular focus detection area that will focus the image optimally for the preponderance of the faces in the scene. (Alternatively, the focus could be set optimally for the largest face in the scene, which is presumed to constitute the primary subject.) 
   Exposure and flash determination. The camera  10  provides automatic exposure control and flash engagement through its exposure control algorithm  82  and flash control algorithm  84 . A typical microprocessor-controlled exposure control apparatus is disclosed in U.S. Pat. No. 4,503,508, which is incorporated herein by reference, and used for both ambient and flash exposure. The exposure control functionality provided by this patent can be confined to, or weighted for, a facial area located within the measuring window  49   a  described in relation to the aforementioned &#39;809 patent. Since people are usually the most important subject in images in which they appear, it is reasonable to choose the exposure to optimize the appearance of the faces of people, unless directed otherwise by the photographer. After performing face detection on the framing image, the camera will use utilize its auto-exposure algorithm  82  to set image exposure optimally in a step  160  for the detection area corresponding to the preponderance of the faces in the scene. (Alternatively, the exposure could be set optimally for the largest face in the scene, which is presumed to constitute the primary subject.) Similarly, the exposure control algorithm  82  will determine whether to fire the flash  27  based on its assessment of the adequacy of the illumination of faces in the scene. If the illumination is inadequate, the flash control algorithm  84  will activate and control the flash unit  27  in a step  170 . 
   Composition aids. The face detecting camera  10  provides a composition-assistance mode in step  180  in which composition advice is provided to the photographer. Many consumer photographs suffer from poor image composition from an aesthetic point of view. Along with improper focus and exposure, poor composition is probably a leading cause of dissatisfaction with consumer image prints. A number of heuristic “rules-of-thumb” have become widely accepted as good principles of composition that result in pleasing images. For example, a small main subject frequently makes for an uninteresting print. Also, the “rule of thirds” calls for the main subject to be placed at roughly the one-third point in the image, either vertically, horizontally, or both. Such principles are discussed in detail in Grill, T. and Scanlon, M.,  Photographic Composition , Amphoto Books, 1990. 
   The face detecting camera  10  provides the composition-assistance mode  180  in which, based on the results of face detection in the framing image, a composition algorithm  92  is enabled to generate composition suggestions that appear in the viewfinder or the display device  34 . The composition algorithm follows the steps expressed in  FIG. 5 , although it should be clear that other composition elements could be examined (such as described in the Grill and Scanlon reference). One aid compares the area of the largest face detected to the overall image area (step  181 ). If the comparison exceeds a threshold (step  182 ) indicating the faces are too small, the display  34  suggests that the camera be moved closer to the main subject (step  183 ). A second aid compares (step  184 ) centroids of faces to grid lines as shown in  FIG. 6  that are representative of the rule of thirds, namely, positions in the image where principal subject matter tends to most pleasing (which is described in more detail in the Grill and Scanlon reference, page 22). If faces are substantially off the grid lines (step  185 ), then the display  34  suggests placing the main subject according to the rule of thirds to achieve a more pleasing image (step  186 ). A third aid locates faces intersecting image borders (step  187 ). If a threshold indicates that a substantial amount of the face is cut off by the camera aperture (step  188 ) then the display  34  is set to alert the photographer (step  189 ). A fourth aid relates the centroids of the faces to a horizontal line (step  190 ). If the faces seem to lie along a common horizontal line (step  192 ) the display  34  suggests that the heights of faces in an image of groups of people be varied, rather than aligned horizontally, to produce a more interesting image. The illustration in  FIG. 5  is meant to be generally illustrative of such an algorithm and other composition principles such as described in the aforementioned Grill and Scanlon reference, which is incorporated herein by reference, may be implemented in a similar fashion. 
   Final Image Mode 
   Immediately after capture and processing of the framing image as shown in  FIG. 3 , the camera is ready to acquire the final image as shown in  FIG. 4 , having provided the photographer with the aids mentioned in steps  150 - 180  as described in the previous section. The initial steps  200 - 240  shown in  FIG. 4  are identical to similarly identified steps  100 - 140  in  FIG. 3 , and therefore will not be further described. Additionally, in  FIG. 4 , further aids operate directly on the final image. As mentioned before, the photographer may choose to operate only with a final image (eliminating the framing image) if only the second group of aids is desired. Alternatively, if the framing image seen on the display device  34  was deemed satisfactory to the user, it can be saved as the permanent image. In either case, several services are provided as part of the final image mode, including optimal color balance, red eye notification and correction, orientation marking and face labeling, as follows. 
   Optimal color balance. While the human visual system demonstrates marvelous ability to maintain perceptual constancy of colors across different scene conditions, neither analogue nor digital cameras possess the same capability. For example, to the human eye, the color of an object appears the same whether the object is viewed in sunlight, sky-light, or tungsten light; whereas these three scene conditions, when captured on a single type of photographic film, will necessarily lead to the reproduction of very different colors. Therefore, it is customary to apply color balancing algorithms (CBAs) to captured images prior to printing or other display of the images. The current state-of-the-art of automated color balance algorithms seeks mainly to compensate for the most prominent scene illuminant. 
   A better job of color balancing an image can be performed by taking into account some understanding of the nature of the objects in the scene, and their relative importance. If an entire scene be reproduced correctly, and yet the color of faces is noticeably wrong, then the reproduced image will not be acceptable. People are very sensitive to incorrect reproductions of skin tones, although the specifics of perceived offenses of reproduction vary from culture to culture. The variations in skin tones among different persons and ethnic groups can be statistically categorized and understood. Furthermore, it fortuitously happens that the natural variations of skin colors and the offensive errors in skin color reproduction tend to lay in orthogonal directions in properly selected color space representations. Skin colors vary along the blue-red dimension, while unacceptable reproduction errors primarily concern the green-magenta dimension. 
   Knowledge of the presence and location of faces in a scene can lead to improved color balancing in two different ways. If only global image correction is available (as in optical printing of analogue images), then the estimate of global illumination can be adjusted so as to result in a pleasing rendering of the skin tones of the faces. The face detecting camera, by recording the location and sizes of faces in the magnetic layer of the analogue film medium  25 , enables later optical photofinishing equipment to optimize the color balance for proper reproduction of skin tones on the face. On the other hand, if a digital processing step is available, then the facial region can be corrected independently of more global considerations of illumination. This is the best possible scenario, leading to a better print than could be obtained by solely optical means, because both the primary subjects (people) and the background regions can be pleasingly reproduced. In either case, the camera  10  utilizes its color balance algorithm  88  in a face preferential correction step  260  to provide optimal color balance for the image based at least in part upon the located faces. More specifically, the CPU  30  interacts with the measuring frame  49   a  generated by the tracking stage  49  to collect color data from the detected face(s) and then to weight the color balance algorithm  88  for the facial area. 
   Red eye notification and correction. A red-eye detection algorithm  80 , such as the one disclosed in commonly assigned U.S. Pat. No. 5,432,863, which is incorporated herein by reference, is run in the red eye correction step  270  against the final captured image. The detected presence of a face is used as additional evidence in the red-eye algorithm  80  to help prevent false positive errors. A pair of detected red-eyes should be corroborated by the re-enforcing evidence of facial presence. The existence of red eye can also be provided by the red eye detection algorithm to the display interface  70 , which can designate an appropriate warning in the display device  34 . After receiving red-eye notification, the photographer may choose to obtain another image. Or, the automatic red-eye correction algorithm can be invoked to remove the offensive red highlights in the eyes if the camera  10  is a digital camera. 
   Orientation marking. Many consumer photo-finishing orders are now returned with an index print of small versions of each image in a sequence. The utility of the index print is diminished if the images are not all printed in the proper natural orientation. The presence of faces in an image provides a powerful cue as to its proper orientation. For instance, the facial dimensions can be separated into their principle axes, and the longest axis can be taken as the up-down axis; then one of the face detection algorithms to be described can distinguish the hair region and thereby infer an upright orientation. The majority of faces will be upright or close to upright, in the sense of overall image orientation. The face detection algorithm  90  in the face detecting camera  10  will determine orientation and tag each captured image on the image storage device  32  (or  25 ) with a notation of the proper orientation as suggested by the face orientation detected in the orientation step  280 . 
   Face labeling. Once faces have been detected, a simple face recognition algorithm can be applied to identify faces from a small gallery of training faces that the camera has previously captured with help from the user and stored in the training data base  72 . The gallery could contain the individuals in a family, for example, or children in a school class. When a new image has been captured by the camera, and the faces detected, the identity of each individual, established by the face recognition algorithm, can be recorded with the image in the digital storage  32  or magnetic layer of the film  25 . Such face identity information flows with the image into photofinishing or subsequent computer processing. The information can be used to automatically label prints with the names of the people in the image. Other possible applications include automatically producing albums that contain images of a single person or a group of persons specified by the customer. For a typical face recognition algorithm, there are a number of commercially available face recognition products available that offer software development kits, allowing their algorithms to be embedded as larger systems. For example, the “Face-It” system produced by Visionics Corp. would be suitable for use as a face recognition algorithm. 
   Face Detection Algorithms 
   A face detection algorithm that operates in a digital camera must meet the criteria necessary for success given limited computational and computer memory resources. That is, the algorithm must operate rapidly (say, in less than one second) and with sufficiently high performance in terms of true positive/false positive detection rates. Counterbalancing the limited resource base, the fact that the results of the algorithm will be presented to or used by a human operator implies that some tolerance will exist for algorithm failures. This tolerance is an enabling characteristic of the proposed invention. 
   In this embodiment, we propose for usage a combination of two face detection algorithms whose joint usage provides higher performance in terms of detection levels than either algorithm individually. The first detector, component W, is a very fast pre-screener for face candidates. The second detector, component S, is a sophisticated pattern matching algorithm characterized by a very low rate of false positives. Face candidates labelled by component W will be subsequently examined by component S to result in a final detection decision. 
   The Component W 
   Wu et al. published a face detection algorithm hereinafter, as modified, the component W) that is well suited for inclusion in a digital camera (see Wu, H., Chen, Q. and Yachida, M., “Face Detection from Color Images Using a Fuzzy Pattern Matching Method”,  IEEE Trans. Pattern Analysis and Machine Intelligence,  21(6), 557-563, 1999, which is incorporated herein by reference). The algorithm is very fast and requires very small amounts of both program memory and trained state. The Component W is a kind of ad-hoc pattern recognizer that searches for image windows that seem likely to contain faces based on color characteristics. The method essentially looks for windows in which the central portion seems likely to contain skin, based on its color and shape; and surrounding regions (around the top and sides of the skin) that seem likely to contain hair, again based on color and shape. Since the method is based on color signals, it requires that the imagery on which it operates be encoded in a meaningful color metric. 
   The component W has a training phase and a test phase. The training phase comprises the collection of skin and hair color distributions, and the gathering of shape models from suitable training examples. In the test phase, a window is scanned over the image and a complete range of scales and positions. The component W implicitly assumes that the upward orientation of the image is known, and that the faces are roughly aligned with the image orientation. This assumption could be relaxed by carrying out the entire face search several times—probably three, since the camera would not be used upside down—once for each possible image orientation. In the test phase, the algorithm applies the following steps once for each image window to be examined:
     1) Compute skin and hair probability maps. Comparison of each pixel in a digitized image with pre-determined probability tables of skin and hair colors, leading to a posteriori probability that the pixel represents human skin or hair. The probability tables must be collected off-line and stored in the camera. They are collected with the same imaging sensor as in the digital camera, using identical spectral sensitivities.   2) Convert probabilities to estimated area fractions via non-linearity. Face shape models are built from training examples, also off-line. These models encode the likelihood of the occurrence of skin and hair colors in each cell of a rectangular grid overlaid on spatially normalized human faces in a small set of standard head poses.   3) Perform fuzzy pattern matching with face shape models. A rectangular window is scanned to each pixel position of the image in turn, and a judgment is made as to whether the window contains a face. To accommodate faces of varying sizes, the scanning process is repeated with windows varying over a range of sizes. The judgment of whether a face is present in a window of the image is based on a fuzzy comparison between the pre-determined face shape models and the actual distribution of posteriori skin and hair probabilities in each cell of the window. The fuzzy comparison makes use of parameterized non-linearities, as described in the Wu et al. article, that are adjusted in a calibration stage in order to provide the best results.
 
Each of these steps are now described in more detail after introducing the face shape models. It should also be understood that extensive detail can be found by referring to the Wu et al. article.
   

   Shape models. The head shape models are low-resolution representations of the spatial distribution of skin and hair in typical face poses. There is one model for skin and one model for hair for each distinct pose. Each model consists of m×n cells (currently, m=12 and n=10), with each cell encoding the fraction of the cell that is occupied by skin (for skin models), or hair (for hair models) for typical heads in a given pose. An image window can be spatially corresponded with the cells in the shape models. Depending on the window resolution, a single pixel or a block of pixels may correspond to each model cell. The models were built using a set of training images to which affine transformations have been applied, in order to place the two eyes in standard positions. The spatially normalized images were then manually segmented into skin and hair regions, and the fractional cell occupancy, at the resolutions of the models, was computed. Examples of the shape models for frontal and right semi-frontal poses are shown in  FIGS. 7A-7D . The models are stored in the training database  72  (shown in  FIG. 1 ) with gray-level encoding of the occupancy fraction. 
   Compute hair and skin probability. The objective at this point is to acquire probability distributions for skin and hair colors from training images. The goal is to obtain probability tables of the form P(skin|color) and P(hair|color). Instead of using the Farnsworth perceptually uniform color space as suggested in the Wu et al. article, the present invention uses (L,s,t) color space as a preferred color metric for distinguishing skin and hair regions, and therefore performs probability training and application in the (L,s,t) color metric, where L=c(R+G+B); s=a(R−b); t=b(R−2G+B); a, b and c are constants; and R, G and B are image values proportional to relative log scene exposure. This metric has proven to be an effective color space in which to perform image segmentation. 
   While all three channels are used, the luminance channel is separated from the combined chrominance channels in the probability histograms. To gather skin color statistics, an annotated database including some 1800 images was used, each image stored in 12 bit, relative log scene exposure RGB metrics. Human judged color balance and white point aims were available for these images, as well as the eye locations of all faces in the database with two eyes visible. Using an anthropometrically average face model, the skin pixels of the faces were extracted for all faces in the database. The color balance and white point aims were also subtracted from the images in each case. The pixel values were then converted to the (L,s,t) metric using the matrix computation: 
             (         L           s           t         )     =       (           1     3             1     3             1     3                 -     1     2             0         1     2                 -     1     6                 2   3             -     1     6               )     ⁢     (           r   ^               g   ^               b   ^           )             
where the hatted quantities have been adjusted for the aim values. To gather hair color statistics, an analogous process was performed, with the exception that the hair regions were manually segmented for each example head. Each pixel of skin or hair results in an example of a color in the (L,s,t) space. Separate probability histograms were accumulated for both hair and skin. The L histograms were compiled separately from the two dimensional s,t histograms in each case. Thus, an implicit assumption is taken that the colors and luminance of skin and hair are independently distributed. At test time, an image is first processed by using the color values at each pixel to look up posteriori likelihoods that either skin or hair was imaged to that pixel. Bayes&#39; theorem is applied to the probability distributions to ensure that the distribution of colors in world objects is taken into account. The result of this computation provides two graphical displays of the skin and hair probability density, as shown in  FIGS. 8A and 8B , and  9 A and  9 B, respectively, where each graphical display represents two views of skin and hair pixel probabilities, respectively, separated between luminance and chrominance components.
 
   Map skin and hair probabilities to estimated area fractions. The shape models contain information about the spatial distribution of colors in face images, while the probabilities computed in the previous step depend on the average color in candidate facial regions. Since they are different, the two categories of information cannot be directly compared. Therefore, an intermediate step is needed to map the probability values in an image window into estimated skin and hair occupancy fractions by the use of a non-linear mapping function. The non-linear function is a sigmoidal-type function with adjustable parameters a and b, and is given by the following equation. 
             S   ⁡     (   x   )       =     {         0         x   ≤   a                 2   ⁢       (     x   -   a     )     2           (     b   -   a     )     2             a   &lt;   x   ≤       (     a   +   b     )     2                   2   ⁢       (     x   -   a     )     2           (     b   -   a     )     2                 (     a   +   b     )     2     &lt;   x   ≤   b             1         b   &lt;   x                   
The Wu et al. article claims to adjust the parameters a and b separately for each of the skin and hair models based on empirical experiment in order to produce the best face detection results. In the present invention, the mapping non-linearity was found to be most useful to compensate for the deficiencies in the statistical sampling of skin and hair colors. For this reason, the parameters a and b are set quite low. The goal is for the component W to almost never miss a face, counting on further processing by algorithm S to eliminate the many false detections that pass through the component W.
 
   Perform fuzzy pattern matching with face shape models. Given the shape model, with skin and area coverage fractions for each cell, and estimates of the same quantities for corresponding image regions coming out of the non-linear mapping, a judgment is made as to the similarity between the image regions and the model cells. The similarity measure uses a two term “fuzzy relation”:
 
similarity( I   s   ,I   h   ,M   s   ,M   h )= e   a dist(I     s     ,I     h     ,M     s     ,M     h     )     b    
 
dist( I   s   ,I   h   ,M   s   ,M   h )=√{square root over (( I   s   −M   s ) 2 +( I   h   −M   h ) 2 )}{square root over (( I   s   −M   s ) 2 +( I   h   −M   h ) 2 )}
 
where the parameters a and b (different from those in the non-linearity mapping of the previous section) determine the shape of the comparison, and the I and M subscripted variables represent the skin and hair probabilities from an image region and a model cell, respectively. Increasing b gives exponentially steeper penalties to differences between the shape model and the image window. In this embodiment, the values a=2 and b=1 were selected after some experimentation. The similarity score for the entire image window is taken as the average similarity score over all cells of the shape model. A threshold can be applied to the similarity measure to identify face candidates detected by the Component W.
 
Component S
 
   Complete details of the Schneiderman algorithm (hereinafter, component S) appear in Schneiderman, H. and Kanade, T., “Probabilistic Modeling of Local Appearance and Spatial Relationships for Object Recognition”,  Proc. CVPR  1998, 45-51, which is incorporated herein by reference. The main steps of the method are outlined here in order to provide a self-contained description and to highlight differences and improvements with respect to the reference. The Component S implements a Bayesian classifier that performs maximum a posterior classification using a stored probability distribution that approximates the conditional probability distribution P(face|image). The method is called Bayesian because of the use of Bayes&#39; theorem to convert the a priori measured training distribution P(image|face) into the posterior distribution in the presence of evidence from an image. The evidence consists of the pixel values in a spatial- and intensity-normalized image window. The use of Bayes&#39; theorem is mandated by the observation that image evidence can be ambiguous. In some cases, objects and scenes not in the class of interest (i.e. faces, in this context) can give rise to image patterns that can be confused with class (=face) objects. Bayes&#39; theorem requires the collection of representative non-class images, known as “world” images. The collection of world images proves to be the most difficult and critical process involved with training the algorithm. The difficulty lies in the fact that the world is very diverse. Faces are not diverse (at least when compared to the world), and so collection of training examples of faces is quite straightforward. This difficulty will be discussed at length in a following section on training. 
   The simplifications made to the distribution
 
P(face|image)  (1)
 
that are described herein change a huge, uncountable distribution into a very practical one. The goal is to arrive at a simplified distribution P(face|distilled-image-features), where the distilled image features can be counted up and grouped during training in, say, one million bins. A heuristic of training classifiers would indicate that two orders of magnitude more examples than bins are needed. Hence, 10 8  examples might be required to populate 10 6  bins in a statistically meaningful way. It is eminently possible to collect that many examples, especially if we are permitted to generate some of them computationally, and if the “unit” of an example is something smaller than an entire human face.
 
   Simplifications are applied in the order listed here and are described in the sections that follow: 
   (1) standardize face region size 
   (2) decompose face region into subregions 
   (3) ignore dependencies between subregions 
   (4) project subregions to lower dimension representation using PCA 
   (5) code projections using sparse coefficients 
   (6) quantize sparse coefficients 
   (7) decompose appearance and position 
   (8) ignore position for uncommon patterns 
   (9) vector quantize positional dependence for common patterns 
   (10) apply (1)-(9) at multiple resolutions, assuming independence between resolutions 
   1. Standardize face region size. Spatially normalized faces will be presented in a 56×56 pixel window. This simplification changes equation (1) into
 
P(face|region)  (2)
 
where region is exactly a rasterized vector of pixels from a 56×56 pixel image window.
 
   2. Decompose face region into subregions. Each face region is decomposed into multiple overlapping 16×16 pixel subregions. These subregions can be anchored at every pixel position in the region, or at a subset of these positions. We anchor subregions at every third pixel in every third line. With this choice, there are 196 possible anchor positions of a subregion within a face region; this position can therefore be encoded in a single byte. On the right hand side of (2), “region” can be replaced with “{subregion} ”, an aggregate of subregions. The subregion size is chosen so that individual subregions, when suitably positioned, are large enough to contain facial features (such as eyes, nose, or mouth). This size limits the largest image feature that can be examined as a coherent unit. 
   3. Ignore dependencies between subregions. No attempt is made to model the statistical dependencies between subregions. This simplification therefore limits the type of object attributes that can be modeled. For example, while a single subregion can contain sufficient pixels to capture an eye, the other eye will fall into a different subregion, and there can be no consideration taken of similarity or dissimilarity between the two eyes. Nor can any reasoning be based on the relative levels of illumination of different parts of the face. Using this simplification, equation (2) can now be replaced with 
                   ∏     i   =   1       #   ⁢           ⁢   subregions       ⁢     P   ⁡     (     face   ❘     subregion   i       )               (   3   )               
where the statistical independence is reflected in the lack of joint dependencies on multiple subregions.
 
   4. Project subregions to lower dimension representation using principal components analysis (PCA). Since subregions contain 256 pixels, with 256 gray levels each, the number of possible subregions is huge. The next simplification involves applying the standard technique of linear PCA to reduce the dimensionality of the subregion from 256 to twelve. (The choice of twelve dimensions is somewhat arbitrary. Upwards of 90% of actual subregion variance can be encoded using no more than twelve dimensions.) To perform the PCA, a large training set of face images was processed, with all subregions participating in the data analysis. Some experimentation was performed to see whether separate principal components are necessitated for different image resolutions and multiple face poses. Based on these findings, it was decided that distinct sets of principal components would be stored for each resolution, but that it was not necessary to keep different sets by face pose. Intuitively, it seems reasonable that at different resolutions the essential facial structures would exhibit unique spatial patterns, while the changes caused by slightly different facial poses would be less significant in the first few principal modes of variation. 
   The result of the projection step is that each image subregion becomes represented by the twelve projection coefficients along the principal component axes. This representation amounts to representing each subregion by a linear combination of twelve principal subregions. The projection operation is carried out by a matrix operation
 
[proj]=A T [subregion]  (4)
 
where A is the projection matrix whose columns contain the eigenvectors (principal components) of the training subregions. Note that the PCA operates on a training set of face images only. False (non-face) examples are not used since the resulting principal components would likely be subject to wide variability caused by statistically inadequate sampling of the very large set of possible non-face images. As a result of this step, expression (3) leads to
 
   
     
       
         
           
             
               
                 
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   5. Code projections using sparse coefficients. Rather than retain all twelve projection coefficients, the subregion representation is further compressed by retaining only the six most significant. However, this sparse coding scheme is further complicated by grouping the last six coefficients pair-wise into groups and considering their sum square values when selecting the six projection dimensions to retain. In this way, twelve coefficients are reduced to six for subsequent processing. 
   6. Quantize sparse coefficients. Further compression of subregion representation occurs through discrete quantization of the nine coefficients using a Lloyd-Max quantizier. This quantizier minimizes the mean-square quantization error under the assumption of a Gaussian distribution of the independent variable. For common values of the number of quantization values, the bin breakpoints and the reconstruction levels of Lloyd-Max quantizers are tabulated in Lim. J.,  Two - Dimensional Signal and Image Processing , Prentice-Hall: N.J., 1990. To test the validity of the Gaussian distribution assumption, the actual distribution of the projection coefficients of the training set were collected, from which it was seen that the Gaussian assumption closely matches the actual distribution. 
   The choice of the number of sparse coefficients retained and the number of quantization levels allocated to each coefficient determines the number of possible quantization values that encode image subregions. Based on the choices of six prominent dimensions, with choices of 8, 4, or 2 quantization levels for each dimension, the algorithm as implemented can represent each subregion by one of approximately 1,000,000 numbers. These quantized numbers are somewhat inscrutably called “q1” values in the Schneiderman et al. reference. The number of possible q1 values is an algorithm sizing parameter referred to as “n q1 ” in that reference. 
   The compression advantage of this quantization scheme becomes clear when it is seen that 256 256  possible subregion patterns are encoded in 10 6  distinct numbers. In fact, it is possible to consider this quantization scheme as a form of image coding. Reconstruction of the image from its coding gives a sort of approximation to the original image.  FIG. 10  shows an original image and its reconstruction following PCA projection and sparse coding and quantization. More specifically,  FIG. 10(   a ) shows the original image,  FIG. 10(   b ) shows a reconstruction from projections of subregions into twelve dimensional principal component space and  FIG. 10(   c ) shows a reconstruction from sparse coded and quantized version of  FIG. 10(   b ). (Note that images (b) and (c) do not show all the encoded information. Rather, they show the reconstructions from the encoding with subregions aligned with a tiled grid of 56×56 face regions. Simultaneous encodings capture further image information as the subregions are offset relative to the region grid.) 
   Following the quantization step, the probability expression (5) is further simplified to 
   
     
       
         
           
             
               
                 
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   7. Decompose appearance and position. At this point in the chain of simplifications of the probability distribution, expression (6) is expanded to explicitly include both the pixel pattern of a subregion and its position within the face region. Equation (6) is replaced with 
                   ∏     i   =   1       #   ⁢           ⁢   subregions       ⁢     P   ⁡     (       face   ❘     q   ⁢           ⁢   1       ,     pos   i       )               (   7   )               
where each subregion is now represented by its quantization value and its position within the face region. Interpretation of expression (7) intuitively leads to thoughts like the following: eye-like patterns ought to occur in face regions only in the subregions likely to contain eyes.
 
   8. Ignore position for uncommon patterns. Given that 1,000,000 quantization levels and 196 positions are possible for each subregion, further simplifications of expression (7) must occur. Two more simplifications are made to this expression. First, a decision is taken to encode the positional dependence of only the most commonly occurring q1 patterns. To this end, a large sorting step orders the q1 patterns by decreasing frequency of occurrence in the training set. All q1 patterns that sort below an occurrence threshold will have their positional dependence replaced by a uniform positional distribution. The number of q1 patterns whose positional distribution is to be explicitly learned during training is an algorithm sizing parameter referred to as “n est ” in the Schneiderman reference. For the uncommon patterns, expression (7) becomes 
                   ∏     i   =   1       #   ⁢           ⁢   subregions       ⁢       P   ⁡     (     face   ❘     q   ⁢           ⁢     1   i         )       npos             (   8   )               
where npos=196 is the number of possible subregion positions.
 
   9. Vector quantize positional dependence for common patterns. The second simplification to expression (7) involves a further reduction in the number of positional distributions learned during training. Already, the simplification of section  8  has reduced the number of positional distributions to be learned from n q1  to n est . Now, a further reduction from n est  to n q2  will be performed by vector quantizing the n est  surviving positional distributions into n q2  representative distributions. For purposes of this quantization, the two dimensional positional distributions of the q1 patterns are rasterized into vectors. The number n q2  is an algorithm sizing parameter. 
   The vector quantization training algorithm is not the standard LBG algorithm, but rather an ad hoc custom algorithm, performed on a single pass through the input vectors. This single-pass nature is important, since the training algorithm will likely be quantizing tens or hundreds of thousands of vectors, and therefore must show concern for speed. The training process is outlined as follows: 
   For each vector x
         Find the closest current pattern center   Calculate the distance d between x and the closest center. The sum squared error (SSE) metric is used.   If d&lt;threshold
           Add x to cluster; update cluster center   
           else
           Seed new cluster with x
 
For this algorithm to function properly, it must of course handle empty clusters gracefully, and also deal with the imposition of a maximum number n q2  of clusters. The cluster centers are computed as the average (ideally, weighted average by occurrence count) of the vectors that map to the cluster. The selection of the distance threshold is problematic and based essentially on empirical observation of the behavior of the quantization training when using different values of the threshold. The goal of this selection is to make full use of the available number of quantization levels while spreading out the distribution vectors as uniformly as possible.
   
               

   Upon application of the vector quantization of positional distributions, the position pos in expression (7) is mapped to one of the VQ pattern centers, identified as pos′. Equation (7) then becomes, for more common patterns, 
   
     
       
         
           
             
               
                 
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   10. Apply detection at multiple resolutions, assuming independence between resolutions. Since the statistical dependencies between subregions cannot be captured in the simplified probability model that has been developed, features larger than subregions cannot be considered. To overcome this limitation, multiple levels of image resolution are now introduced. The entire mechanism of the probability estimator in (2) will be applied to multiple levels of image resolution, leading to 
                   ∏     j   =   1     nmags     ⁢       ∏     i   =   1     nsubs     ⁢     P   ⁡     (     face   ❘     q   ⁢           ⁢     1   i   j         )                 (   10   )               
A typical example would be that of a single face captured at nmags=3 levels of pixel resolution. At each resolution, the eyes must reside at standard positions.
 
   Full form of simplified probability distribution. Gathering together expressions (8) and (10), and applying Bayes&#39; theorem to relate prior probabilities gathered during training to the posterior probabilities in these expressions leads to the full form (11) of the estimated likelihood of face presence in an image region. Details of the complete derivation of this equation appear in the Schneiderman reference. 
                   P   ⁡     (     face   ❘   region     )       =       ∏     j   =   1     nmags     ⁢       ∏     i   =   1     nsubs     ⁢       P   ⁡     (       q   ⁢           ⁢     1   i   j       ❘   face     )       ⁢         P   ⁡     (         pos   ′     ❘     q   ⁢           ⁢     1   i   j         ,   face     )       ⁢     P   ⁡     (   face   )                 P   ⁡     (       q   ⁢           ⁢     1   i   j       ❘   face     )       npos     ⁢     P   ⁡     (   face   )         +         P   ⁡     (       q   ⁢           ⁢     1   i   j       ❘     face   _       )       npos     ⁢     P   ⁡     (     face   _     )                           (   11   )               
In this expression, P(face) and P(  face ) represent the prior probabilities that an image region either does or does not contain a face. In the absence of this knowledge, uniform priors equal to ½ are used, leading to a further simplification in the above expression (11). This assumption about prior probabilities does not affect the performance of the algorithm when used for pattern recognition of faces. Rather, it results in the presence of a scaling factor that must be taken into account when interpreting the algorithm output as a probability value.
 
   Training steps—Phase I. While actual training of algorithm S involves a number of discrete steps, the training divides naturally into two major phases. The goal of the first phase is to obtain specific parameters of the quantization of face subregions. The initial step is to capture the covariance matrix and then principal components of the subregions from the training set. As part of this step, following extraction of the principal components, another pass is made through all the training subregions to gather the statistics of their projections unto those twelve principal dimensions. The projection data are then analyzed. The projection statistics are fed back into the training program to enable optimal design of the Lloyd-Max quantizer. Since the variation of face patterns is quite large when considered across different scales of resolution, this process of extracting principal components and the statistical distribution of the training data along those components must be repeated for each image resolution. 
   Training steps—Phase II. The second phase of training starts by passing through the training set and performing the quantization of each subregion of each face example. As mentioned above, the training set can be expanded by creating slightly perturbed versions of each training exemplar. The frequency with which quantized values appear is counted in a histogram having roughly 1,000,000 bins. Simultaneously, subregion positions at which each quantized value occurs are accumulated. A sort operation arranges the quantization frequency histogram in decreasing order of occurrence count. For the n est  most frequency quantized patterns, the positional distributions enter into the vector quantization algorithm. Following vector quantization, only n q2  seminal positional distributions are retained, and each of the n est  frequent quantization values will have a positional distribution approximated by the retained distributions 
   Applying the face detector. To use the trained face detection algorithm at test time, the computation of expression (1) must be applied to an image region on which spatial and intensity normalization have been conducted. Three different resolution versions of each candidate face region are required. The quantization value for each subregion is computed, and the various probability terms in expression (11) are extracted from the probability tables created during algorithm training. 
   To use expression (11) for face detection, a probability threshold must be selected. When the posterior probability exceeds the threshold, then face detection has occurred. After the algorithm training process has been completed, the threshold is determined by studying the classification performance of the algorithm when applied to a verification set of face and non-face images. The threshold is set for optimal performance on the verification set, taking into account the relative importance of false positive and false negative errors. 
   Dual Screening Face Detector—the Combined Algorithms 
   In the preferred face detection algorithm of the invention, those face candidates generated by the component W become input to the face detector of the component S. Since the window shapes of the two algorithms are slightly different, a spatial affine transformation serves to frame the face candidate and place the eyes in standard position for the component S. A threshold is applied to the output from the component S to declare the presence of a face in an image window. 
   Since the component W examines the image at a range of scales in a window that is scanned across the entire image, it is likely that a true face might be detected at more than one scale, and at several closely spaced window positions. Some method for combination of detection overlaps must be employed. Two different methods were tested. The first method simply used the strongest detection from a spatially overlapping group of detections. The second method computes the average eye locations of the overlapping detections. It was found empirically that the averaging technique resulted in more accurate eye positions, as judged visually by a human observer. 
   The invention has been described with reference to a preferred embodiment. However, it will be appreciated that variations and modifications can be effected by a person of ordinary skill in the art without departing from the scope of the invention. 
   PARTS LIST 
   
       
         10  camera 
         20  image capture section 
         21  optical section 
         22  image 
         23  image sensor 
         24  exposure control mechanism 
         25  analog storage device 
         26  recording device 
         27  flash 
         28  optical viewfinder 
         29  LCD overlay 
         29   a  LCD driver 
         30  CPU 
         32  digital memory 
         34  display device 
         40  system bus 
         42  RAM 
         44  ROM 
         46  I/O adapter 
         48  communication adapter 
         49  target tracking stage 
         49   a  measuring frame 
         50  user interface adapter 
         52  shutter button 
         54  flash controls 
         56  programmed exposure selection 
         58  user manipulated display cursor 
         60  algorithm interface adapter 
         70  display interface 
         72  training database 
         74  pattern signal generator 
         80  redeye correction algorithm 
         82  exposure control algorithm 
         84  flash control algorithm 
         86  focus control algorithm 
         88  color balance algorithm 
         90  face detection algorithm 
         92  composition algorithm 
         100 - 180  steps 
         181 - 192  steps 
         200 - 280  steps