Patent Grant
7796872
The present invention relates generally to digital photography, and more particularly to electronic image stabilization.
A common problem associated with capturing images with a handheld device (e.g., a camera phone) is that the images often become blurred (or distorted) as a result of the shaking of the handheld device due to hand jitter. Hand jitter is fundamental to human biology, and generally cannot be trained away, even for a professional photographer. The amount of blur in an image depends on many factors, including the amount of shaking and the length of the exposure time. Devices with low mass will tend to shake more, and devices with smaller pixels generally require longer exposure times. Current trends in handheld image capturing devices lead toward smaller and smaller units with smaller pixels, exacerbating the problem associated with blurred images. The consumer demand for higher pixel densities and optical zoom capabilities also increases the problem. For example, for a VGA resolution image capture system, a certain blur may be too small to be visible; but for a 3 MP (megapixel) image capturing system, the same blur will be easily apparent.
Various image stabilization techniques have been proposed to deal with distortion in an image. Image stabilization techniques can be generally categorized as optical image stabilization (OIS)—in which a lens or image sensor is mechanically moved in order to compensate for the shaking of a handheld device, digital image stabilization (DIS)—in which pure software is used to remove blur (or other distortion) from an image, or electronic image stabilization (EIS)—in which information from, e.g., a gyroscope, is used to augment a software algorithm to provide a stable image. Optical image stabilization is generally considered the most effective method for producing stable images as the technique mechanically prevents an image from becoming blurred through the use of actuators. However, conventional actuators are generally too large and expensive for adoption into smaller consumer devices such as camera phones. Convention digital image stabilization techniques for removing blur from an image using pure software requires substantial processing, and often results in images that are not useable.
With regard to electronic image stabilization, conventional systems typically read a series of images (or frames) from an image sensor, shift the images using gyroscope data, and combine the images to produce a single sharp image. However, such systems are limited by the read-out time of the image sensor and suffer non-linearities in pixel integration. For example, one conventional technique for combining a short exposure frame with a long exposure frame into a single frame is described in U.S. Patent Application Publication No. 2006/0017837, entitled “Enhancing Digital Photography”. According to this technique, the long exposure frame is used to provide data in which there are not many details, and the short exposure frame is used to provide fine details. However, this technique discards useful data from a long exposure frame that may be used to electronically stabilize an image. In addition, the long exposure frame may contain blur properties (e.g., non-linear blur properties) that are difficult to correct.
In general, in one aspect, this specification describes a method for electronically stabilizing an image captured by a device including a motion detection unit. In particular, the method includes capturing a first exposure of the image, and capturing a second exposure of the image including using the motion detection unit to ensure that the second exposure of the image has a pre-determined blur property. The second exposure being longer than the first exposure. The method further includes combining the second exposure of the image having the pre-determined blur property and the first exposure of the image to electronically stabilize the image captured by the device.
Implementations can include one or more of the following features. The motion detection unit can comprise one or more of a gyroscope, an accelerometer, a magnetic field sensor, an ultrasonic transducer, or an image processor. The gyroscope can comprise a microelectromechanical systems (MEMS) gyroscope, a piezo gyroscope, or a quartz gyroscope. The MEMS gyroscope can comprise a dual-axis MEMS gyroscope. Using the gyroscope to ensure that the second exposure of the image has a pre-determined blur property can include ensuring that an output reading of the gyroscope indicates a pre-determined movement of the device during the second exposure. The pre-determined movement of the device during the second exposure can correspond to a substantially linear movement of the device. Combining the second exposure of the image having the pre-determined blur property and the first exposure of the image to electronically stabilize the image captured by the device can include—performing edge detection in the second exposure of the image to detect edges that are substantially parallel to the linear movement of the device to isolate usable edges from the second exposure of the image; and combining the useable edges from the second exposure of the image with edges in the first exposure of the image that are not substantially parallel to the linear movement of the device.
Implementations can further include one or more of the following features. Performing edge detection in the second exposure of the image to detect edges that are substantially parallel to the linear movement of the device can include using an edge detection algorithm. The edge detection algorithm can comprise wavelet edge detection. The first exposure can be substantially (e.g., +/−3 ms or greater) in the range of 5 ms-50 ms and the second exposure can be approximately 4-16 times longer than the first exposure. A duration of the short exposure and a duration of the long exposure are based upon a motion of the device and ambient lighting conditions. The device can comprise one of a camera phone or a compact digital still camera. The method can further include capturing a third exposure of the image including using the motion detection unit to ensure that the third exposure of the image has the pre-determined blur property (in which the third exposure is also longer than the first exposure), and combining the second exposure of the image having the pre-determined blur property and the first exposure of the image can additionally include combining the third exposure of the image having the pre-determined blur property to electronically stabilize the image captured by the device.
In general, in another aspect, this specification describes a device including a motion detection unit, and an image generator to capture a first exposure of an image in which the first exposure is a short exposure. The image generator is operable to further capture a second exposure of the image including using the motion detection unit to ensure that the second exposure of the image has a pre-determined blur property, in which the second exposure is longer than the first exposure. The device further includes a processor to combine the second exposure of the image having the pre-determined blur property and the first exposure of the image to electronically stabilize the image.
Implementations can provide one or more of the following advantages. In one aspect, a method of electronic image stabilization (EIS) is disclosed which involves combining an understanding of gyroscopes with an understanding of image processing. In one implementation, a gyroscope is used to provide information (e.g., regarding blur properties) of an image to an image processing system without requiring extensive and unreliable image processing necessary to extract such information from the image itself. Gyroscope-based software image stabilization allows the image processing system to be more reliable, more advanced at removing large amounts of blur, use less memory and processing power, and produce higher quality images.
The details of one or more implementations are set forth in the accompanying drawings and the description below. Other features and advantages will be apparent from the description and drawings.
Like reference symbols in the various drawings indicate like elements.
The present invention relates generally to digital photography, and more particularly to electronic image stabilization. The following description is presented to enable one of ordinary skill in the art to make and use the invention and is provided in the context of a patent application and its requirements. Various modifications to implementations and the generic principles and features described herein will be readily apparent to those skilled in the art. Thus, the present invention is not intended to be limited to the implementations shown but is to be accorded the widest scope consistent with the principles and features described herein.
One or more second frames of the image are captured (e.g., by image sensor 102) having a pre-determined blur property (step 204). In one implementation, the pre-determined blur property is a substantially linear blur. More generally, the pre-determined blur property can be any blur property having known characteristics—e.g., a Gaussian blur. While any type of blur may be removed by this system, the algorithm can be faster and more effective if the type of blur is constrained. In one implementation, prior to capturing one or more second frames of the image having a pre-determined blur property, data from the motion detection unit is examined to determine a maximum exposure time that can provide an image having the pre-determined blur property. Accordingly, (in one implementation) after one or more of the second frames of an image have been captured, data from the motion detection unit during a time of the exposure of a given frame can be examined to determine whether a given frame (not having the pre-determined blur property) should be discarded. In one implementation, the exposure time for capturing the one or more second frames of the image is approximately 4-16 times longer than the first exposure.
One or more of the first frames of the image are combined with one or more of the second frames of the image (e.g., by image processor 106) to electronically stabilize the image (step 206). In an implementation in which the pre-determined blur is a substantially linear blur, the image processor performs edge detection in the one or more second frames of the image to detect edges that are substantially parallel to the linear blur to isolate usable edges from the one or more second frames of the image. That is with a substantially linear blur, sharp edges can be retrieved from one or more of the second frames of the image that are in the direction of the blur, as such edges are not blurred. The edge detection may be at a single scale, or at multiple scales. In one implementation, data from the motion detection unit is used to determine a direction of the blur associated with a given second frame of the image. A point spread function (PSF) can also used (in conjunction with data from the motion detection unit) to determine blur characteristics of a given image frame, as discussed in greater detail below. Thus, the useable edges from the one or more second frames of the image can be combined (by the image processor) with edges in the one or more first frames of the image to substantially remove blur (or distortion) from the captured image. Such a technique requires less processing relative to conventional techniques that discard all edge information associated with frames of an image captured using a longer exposure time.
A determination is made whether the gyroscope data indicates that the image capturing system has moved by more than one pixel (i.e., there is a new pixel) (step 412), and if so, the X and Y coordinates associated with the pixel pointer are moved according to the amounts indicated by the yaw and pitch gyroscope data (step 414). The pixel value is incremented as indicated by the pixel pointer—i.e., the pixel being incremented is the pixel currently being pointed to by the pixel pointer within the point spread function (step 416). A determination is made whether the end of data has been reached (step 418), and if so, the point spread function frame shift is output from the point spread function generator (step 420). Otherwise, the gyroscope pointer is updated (step 422), and the method 400 returns to step 406, as discussed above. This is repeated until the gyroscope pointer has incremented through all of the gyroscope data corresponding to the exposure time of the image. In addition to providing the PSF corresponding to the motion of an image capturing system during an exposure time, the gyroscope can provide the shift of the image capturing system between two exposure times. In this case, it is not necessary to perform the complete PSF calculation; instead, the scaled gyroscope data can be used directly. After integrating and scaling the gyroscope data during the time between exposure times, the difference between the first and last values provides the total shift of the image capturing system.
The PSF contains useful information about the image that can be used at various points within the system. When aligning two frames, in addition to knowing the shift between the frames, it is necessary to locate the brightest points of the two PSFs, and their deviations from the center of the PSF. The total amount an image should be shifted in order to line up with another image is equal to the deviation from the center of the brightest point of the first PSF, plus the total shift of the image capturing system between the two frames, plus the total deviation from the center of the brightest point of the second PSF. In some cases, blurry images cause edges to separate into double edges, as is shown in the image 500 of
The PSF can also be used to determine a type of blur contained in a given frame of an image. For example, referring to
With a tri-axis gyroscope or six-axis IMU (Inertial Measurement Unit), the rolling motion of the image capturing system can also be determined. This creates PSFs that vary throughout the frame. If the image capturing system rolls about the center of the image, the PSF at the center will be a bright spot, but the PSFs at the edges of the image will be elongated. In the motion is creating unacceptable blur, the edges of the image may have to be processed differently from the center of the image, and then stitched together with the center of the image using methods that are well known in the art. This is especially true for systems that have a very wide field of view.
With a six-axis IMU, the linear motion of the image capturing system can also be interpreted. The vertical and horizontal translation can be coupled directly into the PSF generation if the distance to the object being captured is known. This has a negligible effect on the PSF of the object being photographed is more than a couple feet away, but for close-ups this effect becomes more important. With a six-axis IMU, the forward-backward motion of the image capturing system can also be used to determine a more accurate PSF. This motion usually has a negligible effect on the image. Like the roll of the image capturing system, it causes no change to the PSF at center of the image, but some outward movement of the PSF near the edges of the image. The edges of the image may have to be processed separately, and stitched together with the center of the image using methods that are well known in the art.
When a rolling shutter is present, it is certain that the PSF will vary extensively throughout the image. As each row of the image is exposed at a slightly different time than the other rows, each row will have experienced slightly different movement. In this case, it will be necessary to split the image into segments, and process the segments separately, and then stitch the segments together (e.g., using conventional techniques). For example, it is often the case with a rolling shutter that for some part of the image, the PSF becomes very small and concentrated. This part of the image is already sharp, and requires no further processing. The other parts of the image should be processed, and then the image can be stitched back together.
In general, rolling shutters are undesirable because they introduce artifacts into images. With a low frame rate, even a short exposure image that is not blurry may have strong rolling shutter artifacts, causing objects to change shape within the image. For example, on a bright sunny day, an exposure time may be as short as 2 ms, and no blur will be present. However, with a frame rate of 5 fps, the time between the exposure of the top of an image and the bottom of an image will be 200 ms, during which the camera will have shifted a significant amount. This is the main reason why mechanical shutters are desired, although they introduce additional cost to a camera system. In addition, these artifacts make any multiple frame technique impossible. Frames cannot be aligned by simply shifting the images once along the X axis and once along the Y axis, because objects have actually changed shape within the images. With a gyroscope, the rolling shutter artifacts can be removed, making frame alignment possible, and reducing the need for a mechanical shutter. Rolling shutter compensation allows enables many multiple frame techniques to be used without mechanical shutters, including dynamic range imaging and red-eye reduction. In addition to enabling multiple frame techniques, rolling shutter compensation can improve the quality of a single frame by changing objects back to their original shapes.
In one implementation, the gyroscope data is integrated between the time of the first row and the time of each additional row. For each row, that row is shifted individually by the amount indicated by the gyroscope data. In one implementation, the upward and downward shifts are implemented in real-time. An upward shift of one pixel is done by writing over the last row with the new row, and a downward shift of one pixel is done by writing the incoming row twice. Shifts of more than one pixel can be accomplished by writing over multiple rows for an upward shift, and writing the incoming row multiple times for a downward shift. The left and right shifts can also be implemented in real-time by writing the row to memory with its starting point at some location other than the first memory location for that row. In one implementation, the rows are shifted using bilinear shifting, which removes some jagged artifacts that may otherwise be introduced by rolling shutter compensation.
Careful synchronizing of the gyroscope data and the image data is extremely important. Hand jitter typically ranges from 3 Hz to 8 Hz, but can contain frequencies as high as 20 Hz. The timing of the gyroscope data relative to the timing of the exposure of the images should be known to 1 or 2 ms. In one implementation, a mechanical shutter is used. This makes synchronization relatively simple, if the exposure times and shutter signal is known. The timing is shown in
In one implementation, the PSF generator may also control the mechanical shutter. For example, for a short exposure in which it is required that no blur be present, the chosen exposure time should be determined to be short enough such that the image capturing system won't move much during this time. When a lot of hand shake is present, it maybe necessary to time the opening of the shutter carefully. For example, the image capturing system may set the analog sensor gains very high, as for a 20 ms “high ISO” shot, but set the exposure time to 100 ms. The PSF generator will then hold the shutter closed during this time and watch the gyro data carefully, and in real time, chose the best 25 ms during which to allow the shutter to open.
When no mechanical shutter is present, and a rolling shutter is used, as shown in
In one implementation, the gyroscope data and the image data may not be easily synchronized at the time of capture. For example, if the EIS solution is designed to be a drop-in module in a system that has already been designed and has no way of easily synchronizing the images to the gyroscope data. If this system uses a rolling shutter, the frame valid line can be used to determine the timing relative to a certain frame, but will not aid the PSF generator in knowing which frame is the one that was captured. For some such systems, there may be a several second delay between the time at which the user decides to take a picture, and the time at which the system actually stores a frame. In this case, it is necessary to stamp all the images with a timestamp that allows a post-processing system to recognize which image corresponds to a certain set of gyroscope data. Such a time-stamping system, as shown in
The time stamp generation includes watching the frame valid line to determine when a frame is present, and watching the line valid line to determine the start of a line. A one-shot circuit A3 for briefly enabling the tri-state driver at the start of the line. A shift register A4 for shifting out a timestamp. A counter A2 for ensuring that each bit in the timestamp is applied to more than one line. For example, to assure some redundancy in the circuit, an 8 bit timestamp may stamp each bit onto 8 lines, creating a timestamp across a total of 256 lines. The timestamp is therefore a vertical bar across the edge of the image, typically only 1 or 2 pixels thick. This bar can be cropped later. Since the uncertainty in matching the gyroscope data to the images is only over a few seconds, it is sufficient to use an 8 bit timestamp, which ensures that over 256 frames, there will be no two frames with the same stamp. At the typical 15 fps rate, this is equivalent to about 17 seconds. In addition, it may be desirable to have the first bit be a start bit, as the timing of the system may be difficult to assure that the timestamp begins on the first line of the image.
In one implementation, when choosing exposure times, it is necessary to consider the lighting in the scene and the amount of shaking in the gyroscope data. It is first necessary to determine the desired PSF size. For an image with zero blur, such as a short exposure frame that is to be used as an edge framework, the PSF must be as small as possible, such as a small bright point that is only one or two pixels in total size. Alternatively, for long exposure images, while it may be impossible to constrain the PSF in size, it may be desire to constrain the PSF to a certain shape. For example, images with a small amount of blur may have PSFs that are Gaussian or linear, which may simplify the calculation. Other images may be rejected. The desired exposure time based on the lighting can be obtained from the autoexposure routing typically built into the sensor and ISP or SoC system.
The exposure time based on hand-shaking should be as long as possible, though no longer than the time determined by the autoexposure, unless it is desired to widen the dynamic range of the image capturing system. The exposure time based on the amount of hand shaking depends on the typical amount of movement. This can be determined experimentally by using a moving integration window over the incoming gyroscope data and determining the average number of data points that can be summed before the PSF is no longer described by the desired constraint. The standard deviation of this value is calculated to determine the longest exposure time that can be used if the desired image is not required every time. For example, rather than requiring that every incoming frame be constrained to a certain PSF, the constraints can be weakened such that only half the incoming frames follow the desired constraint. In this case, it may be necessary to capture a few frames in succession before one of them follows the desired constraint. The advantage is that the captured frame will have a longer exposure time, and therefore lower pixel noise and better color content.
In one implementation, the system uses a two frame approach in which one is long exposure and one is short exposure. The exposure time for the short is set such that about half the short images will have zero blur. The exposure time for the long is set such that about half the images will have linear or Gaussian blur. The image capturing system is then set to take pictures repeatedly until it acquires a short frame with no blur, and a long frame with Gaussian or linear blur. The final constrain is that these images must be close to each other in time, to assure that the gyroscope data will be accurate. It may take a second or two to finally capture these frames, rather than the fraction of a second required if the exposure times are set such that all incoming images obey the constraints. However, the advantage is that, once the images have arrived, they will have lower noise and better color content due to the longer exposure times that were used.
When selecting an image that is to have the least amount of blur, both the magnitude and the sharpness of the PSF must be considered. The magnitude determines the amount of rotation exhibited by the camera during the exposure time. This is not sufficient for selecting the sharpest image. For example, in
In one implementation, the final image is generated by combining a short exposure image with a long exposure image. The short exposure image contains more accurate edge data, and the long exposure image contains better color content and lower pixel noise. The short exposure image may be a grayscale image. In one implementation, long exposure images and short exposure images can be combined using a wavelet transform, known as an image pyramid, as is shown in
If it is known in advance from the gyroscope data that there will be substantial blur in the long exposure image, pixel binning can be initiated at the sensor level, allowing the first pyramid to be done effectively at the sensor level. This reduces computation time and pixel noise. Additionally, if the gyroscope PSF is small enough for the long exposure, no further processing is necessary. The long exposure image can be used immediately as the final image. In order to blend the images without artifacts, it is necessary to first shift the images until the brightest points in their respective PSFs have been aligned. For high megapixel image capturing systems, the gyroscope may not be accurate enough to line the images up to within one or two pixels. In this case, additional image processing may be desired to complete the process down to one or two pixels. However, typically they are unreliable and require extensive processing, due to the fact that there is no known bound on the number of pixels to be shifted; for example, two images may be out of alignment by one pixel, or by one hundred pixels. With the aid from the gyroscope, the alignment problem becomes bounded, and therefore requires much less processing, and is more reliable. For example, if the gyroscope is only accurate to 3 pixels for a given image capturing system, and the frames are misaligned by 50 pixels, the gyroscope data will provide a shift of 47 to 53 pixels. The image processing may be necessary to complete the final image shift. The number of pixels to be shifted is therefore bounded by the error in the gyroscope.
After the images have been aligned as in I4, and the pyramids I2 and I5 have been constructed from the long and short exposure images, they must be blended at I6 to provide a single image that contains the best qualities of both. Image pyramids provide multi-scale low-pass and high-pass versions of the image. These filters provide a natural separation of color content and edge content. When generating the image pyramid, both first and second derivatives of the image are generated. When the first derivative has a peak, and the second derivate has a trough, a strong edge is present. This edge content can be expressed as a complex number having a magnitude and a phase, in which one dimension of the number is the first derivate, and one dimension of the number is the second derivative. In order to blend the images, both must be considered. The final magnitude of the final image can be generated as a weighted average between the magnitude of the short exposure and the magnitude of the long exposure. The final phase of the final image can be generated as a weighted average between the phase of the short exposure and the phase of the long exposure. Since the phase contains strong edge information, it should be taken mostly from the short exposure. However, it should not be taken entirely from the short exposure, as the pixel noise may also seem to be “edge” like, and it is desirable to remove this noise.
In one implementation, the weights are determined experimentally. The magnitude information should be taken from both the short and the long exposure images, with weights that can be determined experimentally. In regions with strong edge content, it may be desirable to weight the short exposure more strongly. In regions without strong edge content, it may be desirable to weight the long exposure more strongly. In the case where the PSF of the long exposure is linear, it may be desirable to weight edges differently depending on the direction. For example, edges along the same direction as the PSF will not be blurry, and these can be weighted more strongly from the long exposure. However, edges that are perpendicular to the direction of the PSF will be blurry, and should be taken more from the short exposure. The direction of the edges can be determined from the pyramid structure using conventional techniques.
Based on the shape and size of the gyroscope PSF, the algorithm may choose different look-up tables with different filter coefficients and blending weights, to optimally produce the best image quality depending on the type of blur in the long exposure. For example, if, based on the gyroscope data, a longer exposure time may be used for the short exposure image, and the gyroscope data has guaranteed that this image still contains little or no blur, then the short exposure frame should be weighted more strongly than the long exposure frame. When the blending is complete, the final image can now be constructed by using the reverse image pyramid transform in I7. By knowing the PSF, the image pyramid computation can be organized optimally to reduce processing time.
In one implementation, a lower lighting condition may be present. In this case, it may not be possible to obtain a short exposure image with sufficiently high edge content and sufficiently low pixel noise. In this case, three frames may be used, in accordance with the method shown in
Various implementations for electronically stabilizing an image have been described. Nevertheless, one of ordinary skill in the art will readily recognize that there that various modifications may be made to the implementations, and those variations would be within the scope of the present invention. For example, in one implementation, it is desired to produce the image along with its thumbnail, for use in an image gallery. It may not be necessary to do any further processing in order to produce the thumbnail, as the image pyramid generates this automatically. The desired level of the pyramid for thumbnail creation should be stored as a separate data structure, and output along with the image. In one implementation, memory can be stored by using a compressed version of the wavelet transform. In one implementation, the algorithm can be run in JPEG2000 space, directly on the coefficients of the JPEG2000 images.
In one implementation, it may be desirable obtain a wide dynamic color range within the image. For example, in images in which some areas are poorly lit and other areas are brightly lit, a single exposure time cannot resolve all areas of the image. Either the image will have parts that are underexposed, or parts that are overexposed. As this system relies on combining short and long exposures, it is possible to achieve a wide dynamic range by simply over exposing the long image instead of using an appropriate exposure time. The blending weights must be adjusted accordingly. In another dynamic, it may be desirable to perform de-convolution on the long exposure using the gyroscope based PSF using conventional techniques. For systems involving a small amount of processing power, it may be required to perform the algorithm on small portions of the image at a time. For example, if the image is 3 MP, but the LCD on the handheld device has only QVGA resolution, the algorithm should be run on the image gradually, one QVGA portion at a time. In this manner, while it may take a long time to finish producing the final image, a user can select any QVGA portion desired and see the result of the algorithm at that portion without any substantial delay.
In one implementation, in which images are transferred from the handheld device to a PC or a remote server, it may be desirable to run the algorithm on the PC or server instead of on the handheld device. In this case, the gyroscope data can be included in a header in the image file, and may be post-processed at a later time.
Accordingly, many modifications may be made without departing from the scope of the present invention.
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