Patent Document

CROSS-REFERENCE TO RELATED APPLICATIONS 
       [0001]    This application is a continuation of U.S. patent application Ser. No. 13/550,064, filed Jul. 16, 2012, now U.S. Pat. No. 8,324,552, which is a continuation of U.S. patent application Ser. No. 13/204,106, filed Aug. 5, 2011, now U.S. Pat. No. 8,222,588, which is a continuation of U.S. patent application Ser. No. 12/640,425, filed Dec. 17, 2009, now U.S. Pat. No. 7,994,462, which is a continuation of U.S. patent application Ser. No. 12/273,879, filed Nov. 19, 2008, now U.S. Pat. No. 7,655,894, which is a continuation of U.S. patent application Ser. No. 11/626,535, filed Jan. 24, 2007, now U.S. Pat. No. 7,459,664, which is a continuation of U.S. patent application Ser. No. 11/545,039, filed Oct. 6, 2006, now U.S. Pat. No. 7,402,786, which is a continuation of U.S. patent application Ser. No. 09/441,341, filed Nov. 16, 1999, now U.S. Pat. No. 7,339,149, which is a continuation of U.S. patent application Ser. No. 09/135,565, filed Aug. 17, 1998, now U.S. Pat. No. 6,097,023, which is a continuation of U.S. patent application Ser. No. 08/621,863, filed Mar. 25, 1996, now U.S. Pat. No. 5,796,094. 
     
    
     BACKGROUND OF THE INVENTION 
       [0002]    This invention relates generally to vehicle control systems and, in particular, to a system and method for controlling the headlights of the vehicles. The invention is particularly adapted to controlling the vehicle&#39;s headlamps in response to sensing the headlights of oncoming vehicles and taillights of leading vehicles. 
         [0003]    It has long been a goal to automatically control the state of a vehicle&#39;s headlights in order to accomplish automatically that which is manually performed by the driver. In particular, the driver of a vehicle whose headlights are in a high-beam state will dim the headlights upon conscious realization that the headlights are a distraction to the driver of an oncoming vehicle or a leading vehicle. It is desirable to relieve the driver of such duties and thereby allow the driver to concentrate on the driving task at hand. The ideal automatic control would also facilitate the use of high beams in conditions which allow their use, increasing the safety for the controlled vehicle as well as reducing the hazard caused by the occasional failure of the driver to dim the headlights when such headlights are distracting another driver. 
         [0004]    Prior attempts at vehicle headlight dimming controls have included a single light sensor which integrates light in the scene forward of the vehicle. When the integrated light exceeds a threshold, the vehicle headlights are dimmed. Such approaches have been ineffective. The headlights of oncoming vehicles are, at least from a distance, point sources of light. In order to detect such light sources in an integrated scene, it is necessary to set a sufficiently low threshold of detection that many non-point-sources at lower intensities are interpreted as headlights or taillights. Such prior art vehicle headlight dimming controls have also been ineffective at reliably detecting the taillights of leading vehicles. The apparent reason is that the characteristics of these two light sources; for example, intensity, are so different that detecting both has been impractical. In order to overcome such deficiencies, additional solutions have been attempted, such as the use of infrared filtering, baffling of the optic sensor, and the like. While such modifications may have improved performance somewhat, the long-felt need for a commercially useful vehicle headlight dimming control has gone unmet. 
       SUMMARY OF THE INVENTION 
       [0005]    The present invention provides a vehicle control which is capable of identifying unique characteristics of light sources based upon a precise evaluation of light source characteristics made in each portion of the scene forward of the vehicle, in the vicinity of each light source, by separating each light source from the remainder of the scene and analyzing that source to determine its characteristics. One characteristic used in identifying a light source is the spectral characteristics of that source which is compared with spectral signatures of known light sources, such as those of headlights and taillights. Another characteristic used in identifying a light source is the spatial layout of the light source. By providing the ability to identify the headlights of oncoming vehicles and the taillights of leading vehicles, the state of the headlights of the controlled vehicle may be adjusted in response to the presence or absence of either of these light sources or the intensity of these light sources. 
         [0006]    This is accomplished according to an aspect of the invention by providing an imaging sensor which divides the scene forward of the vehicle into a plurality of spatially separated sensing regions. A control circuit is provided that is responsive to the photosensors in order to determine if individual regions include light levels having a particular intensity. The control circuit thereby identifies particular light sources and provides a control output to the vehicle that is a function of the light source identified. The control output may control the dimmed state of the vehicle&#39;s headlamps. 
         [0007]    In order to more robustly respond to the different characteristics of headlights and taillights, a different exposure period is provided for the array in order to detect each light source. In particular, the exposure period may be longer for detecting leading taillights and significantly shorter for detecting oncoming headlights. 
         [0008]    According to another aspect of the invention, a solid-state light imaging array is provided that is made up of a plurality of sensors arranged in a matrix on at least one semiconductor substrate. The light-imaging array includes at least one spectral separation device, wherein each of the sensors responds to light in a particular spectral region. The control circuit responds to the plurality of sensors in order to determine if spatially adjacent regions of the field of view forward of the vehicle include light of a particular spectral signature above a particular intensity level. In this manner, the control identifies light sources that are either oncoming headlights or leading taillights by identifying such light sources according to their spectral makeup. 
         [0009]    According to another aspect of the invention, a solid-state light-imaging array is provided that is made up of a plurality of sensors that divide the scene forward of the vehicle into spatially separated regions, and light sources are identified, at least in part, according to their spatial distribution across the regions. This aspect of the invention is based upon a recognition that headlights of oncoming vehicles and taillights of leading vehicles are of interest to the control, irrespective of separation distance from the controlled vehicle, if the source is on the central axis of travel of the vehicle. Oncoming headlights and leading taillights may also be of interest away from this axis, or off axis, but only if the source has a higher intensity level and is spatially larger. These characteristics of headlights and taillights of interest may be taken into consideration by increasing the resolution of the imaging array along this central axis or by increasing the detection threshold off axis, or both. Such spatial evaluation may be implemented by selecting characteristics of an optical device provided with the imaging sensor, such as providing increased magnification central of the forward scene, or providing a wide horizontal view and narrow vertical view, or the like, or by arrangement of the sensing circuitry, or a combination of these. 
         [0010]    The present invention provides a vehicle headlight control which is exceptionally discriminating in identifying oncoming headlights and leading taillights in a commercially viable system which ignores other sources of light including streetlights and reflections of the controlled vehicle&#39;s headlights off signs, road markers, and the like. The present invention further provides a sensor having the ability to preselect data from the scene forward of the vehicle in order to reduce the input data set to optimize subsequent data processing. The invention is especially adapted for use with, but not limited to, photoarray imaging sensors, such as CMOS and CCD arrays. 
         [0011]    These and other objects, advantages, and features of this invention will become apparent upon review of the following specification in conjunction with the drawings. 
     
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         [0012]      FIG. 1  is a side elevation of a portion of a vehicle embodying the invention; 
           [0013]      FIG. 2  is a partial side elevation view and block diagram of a vehicle headlight dimming control system according to the invention; 
           [0014]      FIG. 3  is a block diagram of the control system in  FIG. 2 ; 
           [0015]      FIG. 4  is a layout of a light-sensing array useful with the invention; 
           [0016]      FIG. 5  is a block diagram of an imaging sensor; 
           [0017]      FIG. 6  is an alternative embodiment of an imaging sensor; 
           [0018]      FIGS. 7   a - 7   d  are a flowchart of a control program; 
           [0019]      FIGS. 8   a - 8   c  are spectral charts illustrating spectra regions useful with the invention; 
           [0020]      FIG. 9  is the same view as  FIG. 3  of another alternative embodiment; 
           [0021]      FIG. 10  is the same view as  FIG. 2  of an alternative mounting arrangement; 
           [0022]      FIGS. 11   a - 11   c  are views forward of a vehicle illustrating different forms of spatial filtering; and 
           [0023]      FIGS. 12   a  and  12   b  are illustrations of use of the invention to detect particular atmospheric conditions. 
       
    
    
     DESCRIPTION OF THE PREFERRED EMBODIMENT 
       [0024]    Referring now specifically to the drawings and the illustrative embodiments depicted therein, a vehicle  10  includes a vehicle headlight dimming control  12  made up of an imaging sensor module  14  which senses light from a scene forward of vehicle  10 , an imaging control circuit  13  which receives data from sensor  14 , and a vehicle lighting control logic module  16  which exchanges data with control circuit  13  and controls headlamps  18  for the purpose of modifying the headlight beam ( FIGS. 1 and 2 ). Such control may be a binary control of the aim of the beam, such as by switching between lamps or lamp filaments, or may be a continuous variation of the aim of a single lamp more or less forward of the vehicle. The control may also control the intensity or pattern of the beam. Additionally, the lights of a vehicle equipped with daytime running lights may be switched between a daytime running light condition and a low-beam condition. Vehicle headlight dimming control  12  can perform a wide range of additional control operations on the vehicle, including turning the headlights ON and OFF, modifying the light intensity of the instrument panel, and providing an input to an electro-optic mirror system. 
         [0025]    Vehicle lighting control logic module  16  receives an input  20  from imaging control circuit  13 . In particular embodiments, such as ones which adjust the state of the headlights between continuously variable states, module  16  may supply data to imaging control circuit  13 , such as the speed of the vehicle, which may be combined with the data sensed by imaging sensor  14  in establishing the state of headlights  18 . In the illustrated embodiment, imaging sensor module  14  may be fixedly mounted in a housing  28  by a bracket  34  mounted to, or near, the vehicle&#39;s windshield  32 . Bracket  34  also mounts an interior rearview mirror  30 . This is a preferred mounting for imaging sensor module  14  because the location within the interior of the vehicle substantially eliminates environmental dirt and moisture from fouling the light sensor module. Additionally, the position behind windshield  32 , which typically is kept relatively clear through the use of washers and wipers and the like, ensures a relatively clear view of the scene forward of vehicle  10 . Alternatively, imaging sensor module  14  may be mounted within a housing  29  of interior rearview minor  30  facing forward with respect to vehicle  10  ( FIG. 10 ). In such embodiment, control circuit  13  may be combined with the circuit which controls the partial reflectance level of minor  30  if minor  30  is an electro-optic mirror such as an electrochromic mirror. Other mounting techniques for sensor module  14  will be apparent to the skilled artisan. 
         [0026]    Imaging sensor module  14  includes an optical device  36 , such as a lens, an array  38  of photon-accumulating light sensors, and a spectral separation device for separating light from the scene forward of vehicle  10  into a plurality of spectral bands, such as a filter array  40  disposed between optical device  36  and light-sensing array  38 . Light-sensing array  38  is described in detail in application Ser. No. 08/023,918 filed Feb. 26, 1993, now U.S. Pat. No. 5,550,677, the disclosure of which is hereby incorporated herein by reference. Light-sensing array  36  includes a plurality of photosensor elements  42  arranged in a matrix of columns and rows ( FIG. 4 ). In the illustrated embodiment, an array of 512 rows and 512 columns of light-sensing pixels, each made up of a photosensor element  42  is utilized. However, a greater or lesser number of photosensor elements may be utilized and may be arranged in matrix that is laid out in other than columns and rows. Each photosensor element  42  is connected to a common word-line  44 . To access the photosensor array, a vertical shift register  46  generates word-line signals to each word-line  44  to enable each row of photosensor elements  42 . Each column of photosensor elements is also connected to a bit-line  48  which is connected to an amplifier  50 . As each word-line  44  is accessed, a horizontal shift register  52  uses a line  54  to output the bit-line signals on consecutive bit lines  48  to an output line  56 . In this manner, each photosensor element  42  may be individually accessed by appropriate manipulation of shift registers  46  and  52 . Output  56  is supplied to a digital signal processor  13  which is supplied on an output  62  as input to control circuit  13  ( FIGS. 3-5 ). 
         [0027]    Digital signal processor  13  includes an analog-to-digital converter  58  which receives the output  56  of array  36  and converts the analog pixel values to digital values. A digital output  68  of A/D converter  58  is supplied to a taillight detection circuit  76 , a headlight detection circuit  78 , and to ambient sense logic circuit  84 . A detection control circuit  72  supplies control and timing signals on a line  74  which is supplied to array  38 , A/D converter  58  taillight detection circuit  76 , headlight detection circuit  78 , and ambient sense logic  84 . Such signals coordinate the activities of these modules and provide any data, from look-up tables provided in control circuit  72 , needed by each circuit to perform its function. For example, control circuit  72  may provide intensity threshold levels to taillight detection circuit  76  and headlight detection circuit  78 . 
         [0028]    Taillight detection circuit  76  detects a red light source having an intensity above a particular threshold as follows. For each pixel that is “red,” a comparison is made with adjacent “green” pixels and “blue” pixels. If the intensity of a red pixel is more than a particular number of times the intensity of the adjacent green pixel and adjacent blue pixel, then it is determined that the light source is red. If the intensity of the “red” light source is greater than a particular threshold, an indication is provided at  80 . 
         [0029]    Headlight detection circuit  78  detects a white light source having an intensity above a particular threshold as follows. A white light is a combination of red, green, and blue components. If adjacent “red,” “green,” and “blue” pixels all exceed a particular threshold, a ratio comparison is made of the pixels. If the ratio of the intensity of the adjacent “red,” “green,” and “blue” pixels is within a particular range, such as 20 percent by way of example, then a white light source is detected. 
         [0030]    Vehicle headlight dimming control  12  additionally includes an ambient light-sensing circuit  84  which receives an input from digital output signal  68 . Ambient detection circuit  84  samples a subset of photosensor elements and detects light levels sensed by the subset over a long period of time in order to produce significant time filtration. Preferably, the photosensor elements in the sensed subset include sensors that detect portions of the forward-looking scene that are just above the earth&#39;s horizon which is more indicative of the ambient light condition. Ambient detection circuit  84  produces an indication  88  of ambient light levels which is supplied as an input to a lighting control module  90 . A high ambient light level may be used by a module  90  to inhibit headlight actuation or to switch headlights  18  to a daytime running light mode. Ambient detection circuit  84  can, optionally, perform other functions, such as switching the daytime running lights of the vehicle between daytime and nighttime modes, controlling the intensity of the vehicle&#39;s instrument panel and providing an input to an electro-optic rearview minor system. 
         [0031]    Indications  80  and  82  from the light detection units and indication  88  from ambient detection circuit  84  are supplied to a lighting control circuit  90  which produces a first indication  92  that headlights  18  are to be switched on, or switched from a daytime running condition to a night mode, and a high-beam enable indication  94  that the headlights may be switched to a high-beam state. Vehicle lighting control logic module  16  responds to indications  92  and  94  by switching headlights  18  to an appropriate mode. An output  96  from module  16  may be provided to supply lighting control circuit  90  with information with respect to vehicle telemetry, steering, speed, and any other parameter that may be incorporated into the algorithm to determine the state of the headlights of the vehicle. Digital signal processor  13  may be implemented using discrete digital circuit modules or with a suitably programmed micro-processor with input and output buffers. 
         [0032]    In one embodiment, an imaging sensor module  14   a  includes a single photosensor array  38   a , one spectral filter array  40   a , and one optical device  36   a  ( FIG. 5 ). In this illustrated embodiment, spectral filter array  40   a  includes alternating spectrum filter elements for exposing adjacent pixels to different regions of the electromagnetic spectrum in the red band or green band or blue band. This may be accomplished by arranging such filter elements in stripes or by alternating filter spectral regions in a manner known in the art. Digital signal processor  13   a  captures a frame of data by enabling photosensor array  38   a  for a particular exposure period during which each photosensor element  42  accumulates photons. In order to detect oncoming headlights, digital signal processor  13   a  enables photosensor array  38   a  for a first exposure period. In order to detect leading taillights, digital signal processor  13   a  enables photosensor array  38   a  for a second exposure period. Because oncoming headlights have an intensity level that is substantially greater than that of leading taillights, the exposure period of the frame in which leading taillights is detected is at least approximately ten times the length of the exposure period during which oncoming headlights are detected. Most preferably, the exposure period for detecting leading taillights is approximately 40 times the exposure period for detecting oncoming headlights. In the illustrated embodiment, an exposure period of 0.004 seconds is utilized for detecting taillamps and 0.0001 seconds for detecting oncoming headlamps. The exposure period is the time during which each photosensor element  42  integrates photons before being read and reset by digital signal processor  13   a . Establishing a different exposure period for detecting headlights verses taillights facilitates the use of existing and anticipated sensor technology by accommodating the dynamic range of such sensor technology. Exposure may also be adaptively established on a priority basis. In one such embodiment, exposure is set to a shorter headlight setting. If headlights are detected, the headlights  18  of vehicle  10  are dimmed and the exposure period is kept short. If no headlights are detected, the next frame is set to a longer exposure period. This has the advantage of shorter system cycle time as well as a reduction in sensitivity to sensor saturation and blooming. In another such embodiment, the exposure period is initially set to a long period. If an oncoming headlight is tentatively detected, the exposure period could then be switched to a short period to confirm the observation. 
         [0033]    Vehicle headlight dimming control  12  carries out a control routine  100  ( FIGS. 7   a - 7   d ). At the beginning of each pass through the routine, which occurs for every frame captured by the imaging sensor, a frame is grabbed at  102  and all of the pixels in the frame are processed as follows. Counters used for detecting white headlight sources and red taillight sources are zeroed at  104 . It is then determined at  106  whether the previously processed frame was for detecting headlights or taillights. This is determined by looking at a variable “process.tails” which will be set to “yes” if the previous frame was processed to detect headlights and will be set to “no” if the previous frame was processed to detect taillights. If it is determined at  106  that the variable “process.tails” is set to “yes,” the control proceeds to  108  in order to process the next frame to detect taillights. If it is determined at  106  that the variable process.tails is set to “no,” then control passes to  109  in order to process the next frame as a headlight detecting frame. 
         [0034]    The taillight detecting frame process begins at  108  by setting the exposure period for the imaging sensor module to grab the next frame according to a headlamp exposure level. In the illustrated embodiment, the exposure period for detecting headlights is set at 0.0001 seconds. Processing of the taillight frame proceeds at  110  by examining, for each “red” pixel, whether the intensity of light sensed by that pixel is greater than a threshold and whether the intensity of light sensed by that pixel is greater than a selected number of multiples of the intensity of light sensed by an adjacent “blue” pixel and a selected number of multiples of the intensity of light sensed by an adjacent “green” pixel. If so, then a “red” counter is incremented at  114 . Preferably, the ratio of red pixel intensity to green or blue pixel intensity is selected as a power of 2 (2, 4, 8, 16 . . . ) in order to ease digital processing. However, other ratios may be used and different ratios can be used between red/green and red/blue pixels. In the illustrated embodiment, a ratio of 4 is selected based upon ratios established from CIE illuminant charts known to skilled artisans. Based upon these charts, a ratio greater than 4 would provide greater discrimination. Such greater discrimination may not be desirable because it could result in failure to identify a leading taillight and, thereby, a failure to dim the headlights of the controlled vehicle. After all pixels have been processed, the parameter “process.tails” is set to “no” at  116  and control proceeds to  118  ( FIG. 7   c ). 
         [0035]    In a similar fashion, processing of a headlight frame begins at  110  by setting the exposure period for the imaging sensor module to grab the next frame as a red taillight detecting frame. This is accomplished by setting the exposure period of the imaging sensor module to 0.004 seconds. It is then determined at  120  for each pixel whether an adjacent set of “red,” “green,” and “blue” pixels each exceeds a particular threshold and whether the pixel intensity levels all fall within a particular range, such as within 20 percent of each other. If all of the red, green, and blue pixels exceed a threshold and pass the ratio test, then it is determined that a white light source is being sensed and a “white” counter is incremented at  122 . After all of the pixels in the frame have been processed, the process.tails flag is set to a “yes” state at  124 . Control then passes to  118 . 
         [0036]    It is determined at  118  whether both the “white” and the “red” counters are below respective high-beam thresholds. If so, a high-beam frame counter is incremented and a low-beam frame counter is set to zero at  120 . If it is determined at  118  that both the “white” and the “red” counters are not less than a threshold, it is then determined at  126  whether either the “red” counter or the “white” counter is greater than a respective low-beam threshold. If so, the high-beam frame counter is set to zero and the low-beam frame counter is incremented at  128 . If it is determined at  126  that neither the “red” counter or the “white” counter is greater than the respective low-beam threshold, then both the high-beam frame counters and the low-beam frame counters are set to zero at  130 . 
         [0037]    Control then passes to  132  where it is determined if the low-beam frame counter is greater than a particular threshold. If so, high-beam enable signal  94  is set to a “low-beam” state at  134 . Additionally, the low-beam frame counter is set to the threshold level. If it is determined at  132  that the low-beam frame counter is not greater than its threshold, it is determined at  136  whether the high-beam frame counter is greater than its threshold. If so, high-beam enable signal  94  is set to “high-beam” state at  138  and the high-beam frame counter is reset to its threshold level. 
         [0038]    Control routine  100  provides hysteresis by requiring that a headlight spectral signature or a taillight spectral signature be detected for a number of frames prior to switching the headlights to a low-beam state. Likewise, the absence of a detection of an oncoming headlight or a leading taillight must be made for multiple frames in order to switch from a low-beam to a high-beam state. This hysteresis guards against erroneous detection due to noise in a given frame and eliminates headlamp toggling when sources are at the fringe of detection range. In the illustrated embodiment, it is expected that a vehicle headlight control system  12  will respond to a change in the state of light sources in the forward field of view of the vehicle in less than 0.5 seconds. An additional level of hysteresis may be provided by forcing the headlamps to stay in a low-beam state for a given number of seconds after a transition from high beams to low beams. The reverse would not occur; namely, holding a high-beam state for a particular period to avoid annoyance to drivers of oncoming or leading vehicles. 
         [0039]    In the illustrated embodiment, red light sources, which have the spectral signature and intensity of taillights, are detected by determining that a “red” pixel, namely a pixel which is exposed to light in the visible red band, is both greater than a given multiple of the “green” and “blue” adjacent pixels, as well as being greater than a threshold and that white light sources, which are the spectral signatures of headlights, are detected by determining that “red,” “green,” and “blue” pixels are both within a particular intensity range of each other as well as being greater than a threshold. This double-testing helps to reduce false detection of light sources. However, it would be possible to detect red light sources only by looking at the intensity of “red” pixels and to detect white light sources by determining that an adjacent set of “red,” “blue,” and “green” pixels are all above a particular threshold. 
         [0040]    In the illustrated embodiment, spectral filtering is carried out in a manner which exposes each photosensing element in the photosensor array to a band of light falling within one of the primary ranges of the visible spectrum, namely red, green, or blue as illustrated in  FIG. 8   a . However, different bands in the frequency spectrum may be utilized including not only visible spectrum bands but invisible spectrum bands including infrared and ultraviolet bands as illustrated in  FIG. 8   b . The band selection could also be chosen from visible spectral regions that do not correspond with the primary spectrums. For example, the spectral filter may be selected in order to detect at the pixel level red light sources and the complement of red light sources as illustrated in  FIG. 8   c . These binary indications could be utilized to detect red taillights by determining that the “red” pixel is greater than a threshold and greater than a number of multiples of the intensity sensed by the “red complement” pixel adjacent thereto. Likewise, a white light source indicative of oncoming headlights could be detected by determining that both the “red” pixel and the “red complement” pixel adjacent thereto are both above a particular threshold and within a particular intensity range of each other. It may also be desirable to select bands that fall between primary spectrum regions or any other bands that may be desirable for a particular application. 
         [0041]    Photosensing array  38  may be a charge couple device (CCD) array of the type commonly utilized in video camcorders and the like. Alternatively, photosensing array  38  could be a CMOS array of the type manufactured by VLSI Vision Ltd. (VVL) in Edinburgh, Scotland. Additionally, a hybrid of the CCD and CMOS technology may be employed. Other potentially useful photosensing technologies include CID, MOS, photo diodes, and the like. 
         [0042]    In an alternative embodiment, an imaging sensor module  14   b  includes two or more pairs of photosensor arrays  38   b  ( FIG. 6 ). Each photosensor array  38   b  has an associated spectral filter array  40   b  and optical device  36   b . In this embodiment, each array  38   b  is operated by digital signal processor  58   b  to have an exposure period that is set for detecting either oncoming headlights or leading taillights. In this manner, each frame of the scene captured by each array is utilized to detect a particular light source. This is in contrast to light-sensing module  14   a  in  FIG. 5  in which each light source is detected in alternating frames. Each spectral filter  40   b  is identical, whereby each array  38   b  is capable of detecting light sources having spectrum composition including red, green, and blue regions of the spectrum. However, the spectral filters may be custom configured to the particular application. This may result in a homogeneous composition or a more complex mosaic, especially where light sources are examined in three or more spectral regions. 
         [0043]    In yet an additional single lens system embodiment, an imaging sensor module  14   c  includes three light-sensing arrays (not shown) and a spectral separation device overlying the light-sensing arrays which directs spectral bands to different arrays ( FIG. 9 ). An example of such spectral separation device is a refracting optical splitter, such as dichroic mirrors or prisms. In this manner, each light-sensing array detects light in either the red or green or blue region of the spectrum. As such, imaging sensor module  14   c  produces three output signals on a line  64 , each representing detected light in one of the red or green or blue spectral regions. The output signals on line  64  include frame-timing signals which are decoded by digital acquisition circuits  66  which produces a digital output signal  68 ′ indicative of intensity levels of adjacent red, green, and blue pixels. Digital acquisition circuit  66  additionally produces a timing signal output  70  which is utilized by a detection control circuit  72  in order to supply synchronizing signals, at  74 , to imaging sensor module  14   c  and digital acquisition circuit  66 . A control and timing signal  86  is produced by digital acquisition circuit  66  and supplied to detection circuits  76  and  78  and ambient detection circuit  84  in order to enable the circuits to distinguish between subsequent frames captured by the light-sensing modules. As with previously described embodiments, digital output signal  68 ′ is supplied to taillight detection circuit  76 , headlight detection circuit  78 , and ambient sense logic circuit  84 . 
         [0044]    The present invention is capable of identifying point sources of light in any particular location within the scene viewed forward of the vehicle. Additional discrimination between oncoming headlights and leading taillights may be accomplished by taking into account the relative location of the source of light within the scene. For example, as best seen by reference to  FIG. 11   a , particular relationships have been discovered to exist between light sources of interest and their spatial location forward of the vehicle. Oncoming headlights and leading taillights of interest can be characterized, at least in part, based upon their displacement from the central axis of the vehicle. On-axis light sources of interest can be at both close and far away separation distances. However, off-axis light sources may only be of interest if at a close separation distance from the vehicle. Assuming for illustration purposes that headlights and taillights are of the same size, headlights and taillights of interest occupy an increasing spatial area as they move off axis. Therefore, the resolution required to detect lights of interest may decrease off axis. Additionally, the fact that close-up off-axis light sources have significant spatial area would allow image-processing techniques to be employed to discriminate between close-up off-axis light sources of interest and distant off-axis light sources, which are not of interest. This may be accomplished through customized optics or other known variations in pixel resolution. Furthermore, headlights and taillights of interest are of greater intensity, because of their closeness, off axis. This allows an increase in intensity detection thresholds off axis without missing detection of such light sources. This increase in detection threshold and reduction in resolution off axis assists in avoiding false detection of light sources not of interest, such as a streetlights, building lights, and the like. 
         [0045]    In order to take into account this spatial differentiation, the present invention comprehends detecting light sources at a lower threshold centrally of the scene and at a higher threshold at the periphery of the scene. This may be accomplished either optically, or electronically, or both. Optically, this may be accomplished by providing a non-uniform magnification to optical device  36 . For example, an optical device may have optical magnification at a central portion thereof and an optical attenuation at a peripheral region thereof. Additionally, optical device  36  may have a relatively wide horizontal field of view and a relatively narrow vertical field of view. The narrow vertical field of view would tend to reduce the detection of street lights and other overhead light sources. In a preferred embodiment, optical device  36  is a lens that is made from injection-molded plastic. Electronically, such spatial differentiation may be accomplished by establishing a higher threshold level for pixel intensity detection for pixels located at the periphery of the scene than for pixels located centrally of the scene. This would cause centrally positioned light sources to be detected at a lower intensity level than sources detected at the periphery of the scene. Such spatial differentiation could also be accomplished by a non-symmetrical mapping of light to the sensor array, as illustrated in  FIG. 11   b , or by masking portions  98   a ,  98   b , and  98   c , at the periphery of the scene, as illustrated in  FIG. 11   c , so that these portions are not sensed at all. Spatial differentiation could also be accomplished by providing non-uniform pixel size. 
         [0046]    The present invention is exceptionally sensitive to sources of light having spectral signatures of oncoming headlights and leading taillights. By recognizing the spectral signature of the light sources, many non-relevant light sources may be ignored. By examining light sources pixel-by-pixel, relatively small light sources may be detected at great distances in order to dim the headlights well before they become a nuisance to the driver of the vehicle ahead of the control vehicle. This is accomplished, according to a preferred embodiment, by utilizing an imaging sensor made up of an array of photosensing elements in a compact design which responds to light sources in a scene forward of the vehicle. Furthermore, such sensor preferably utilizes digital processing techniques which are well adapted for use with custom digital electronic circuitry, avoiding the expense and speed constraints of general purpose programmable microprocessors. 
         [0047]    The present invention takes advantage of the spectral signatures both of light sources which must be detected in a headlight dimming control as well as the spectral signatures of light sources which must be rejected in a headlight dimming control. For example, federal regulations establish specific spectral bands that must be utilized in vehicle taillights; namely red. Furthermore, federal legislation prohibits the use of red light sources in the vicinity of a highway. Lane markers, signs, and other sources of reflected light are all specified in a manner which may be readily identified by spectral signature. Oncoming headlights, according to known technology, have a visible spectral signature which is predominantly white light. As light source technology evolves, the present invention facilitates detection of other spectral signatures of light sources in the future. 
         [0048]    The present invention is capable of utilizing spatial filtering to even further enhance the ability to identify light sources. By spatial filtering is meant consideration of not only whether a particular pixel, or pixel group, is detecting a light source having a particular spectral signature, but also what adjacent, or closely related, pixels or pixel groups, are detecting. For example, it can be concluded that very closely adjacent red and white light sources are not of interest as oncoming headlights or taillights. An example where such pattern could be observed is a streetlight observed with a system having imperfect color correction, which can produce a white light surrounded by a red halo. By evaluation of adjacent pixel groups, a closely proximate red light source and white light source can be identified as a streetlight and not either a headlight or a taillight. 
         [0049]    Pattern recognition may be used to further assist in the detection of headlights, taillights, and other objects of interest. Pattern recognition identifies objects of interest based upon their shape, reflectivity, luminance, and spectral characteristics. For example, the fact that headlights and taillights usually occur in pairs could be used to assist in qualifying or disqualifying objects as headlights and taillights. By looking for a triad pattern, including the center high-mounted stoplight required on the rear of vehicles, stoplight recognition can be enhanced. Furthermore, object recognition can be enhanced by comparing identified objects over successive frames. This temporal processing can yield information on object motion and can be used to assist in qualifying or disqualifying objects of interest. 
         [0050]    Spatial filtering can also be useful in identifying atmospheric conditions by detecting effects on light sources caused by particular types of atmospheric conditions. One such atmospheric condition is fog. A bright light source  102  is surrounded by a transition region  104  between the intensity of the light source and the black background ( FIG. 12   a ). Fog, or fine rain, tends to produce a dispersion effect around light sources which causes a series of transition regions  104   a ,  104   b  . . .  104   n  which extend further from the light source ( FIG. 12   b ). By placing appropriate limits on the size of the transition region, fog or light rain, or a mixture of both, or other related atmospheric conditions, can be detected. In response to such atmospheric conditions, vehicle headlight dimming control  12  may activate fog lights, inhibit switching to high beams, or perform other control functions. Furthermore, fog, or fine rain, can be detected, or confirmed, by analyzing the effects of headlights  18  in the forward scene as reflected off of moisture particles. 
         [0051]    Spatial filtering can also be used to detect rain on windshield  32 . This may be accomplished by performing statistical analyses between a pixel, or pixel group, and adjacent pixels or pixel groups. A view forward of a vehicle through a dry windshield would be sensed by an imaging sensor module as continuously varying differences between adjacent pixels, or pixel groups, assumed to be under constant illumination from light sources. When, however, a droplet of water or a snowflake is on windshield  32 , an effect is created which causes a lack of continuous variation of differences between adjacent pixels, or pixel groups. This has the tendency to reduce the first derivative of the pixel, a condition which can be determined by processing. 
         [0052]    Processing can be used to determine the first derivative of an image captured by image-sensing module  14  by determining a measure of the entropy, or disarray, of a pixel, or pixel group, with respect to its neighbors. For example, an approximation of the first derivative for a pixel is: where N=8 and where Pi is a given pixel and Pj is one of 8 neighboring pixels. 
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         [0053]    It should be apparent to those skilled in the art that the invention is capable of performing control functions other than controlling the dimming of the vehicle&#39;s headlights. For example, spectral signature identifications may be utilized to detect the state of a traffic light to either warn the driver that a light has changed from green to yellow to red or to automatically decelerate and stop the vehicle. Also, by sensing that the intensity of a leading taillight has abruptly increased, a condition where the leading vehicle is braking may be identified and suitable action taken. 
         [0054]    The invention may be utilized to identify particular traffic signs by their spectral signature as well as their geometric organization. For example, red octagons may be identified as stop signs, yellow triangles as caution signs, and the like. These capabilities are a result of the present invention providing a significant reduction in the amount of data to be processed because the image forward of the vehicle is captured in a manner which preselects data. Preselection of data is accomplished by configuring the sensor array, including the optics thereof, to consider the spatial, as well as the spectral, characteristics of light sources. 
         [0055]    The present invention may be used to determine the environment in which the vehicle is operated. For example, a high level of “non-qualified” light sources; namely, light sources that are not headlights or taillights, as well as “qualified” light sources can be used to determine a measurement of the activity level around the vehicle; namely, that the vehicle is in an urban environment which may be a useful input for particular control algorithms. This may be accomplished as follows. An activity counter is established which represents a total number of pixels, or pixel groups, whose red, green, or blue components exceed a threshold. The threshold is set to a relatively low value, namely just above the noise floor. This counter, which registers any real detected source, is reset and retabulated every frame, preferably during the exposure period for detecting taillights. If the activity counter exceeds a particular value, then a high activity environment is detected. One use of this information would be to inhibit the control from switching the vehicle&#39;s headlights from a low-beam state to a high-beam state unless a low activity condition exists for awhile. The activity counter may be used by the control in combination with a low-beam duration counter which records the number of frames that the system has been in a low-beam state. It is reset upon system power-up and at every transition from the high-to-low beam states. The control may be inhibited from switching the vehicle&#39;s headlights to the high-beam state unless either the low-beam duration counter exceeds a value or the activity counter indicates a sustained low activity condition. 
         [0056]    The present invention can be used to detect lane markers in order to either assist in steering the vehicle or provide a warning to the driver that a lane change is occurring. The capability of the invention to detect rain on the vehicle&#39;s windshield could be used to control the vehicle&#39;s wipers both between OFF and ON conditions and to establish a frequency of intermittent operation. 
         [0057]    Changes and modifications in the specifically described embodiments can be carried out without departing from the principles of the invention which is intended to be limited only by the scope of the appended claims, as interpreted according to the principles of patent law including the doctrine of equivalents.

Technology Category: 3