Abstract:
A method summarizes unknown content of a video. First, low-level features of the video are selected. The video is then partitioned into segments according to the low-level features. The segments are grouped into disjoint clusters where each cluster contains similar segments. The clusters are labeled according to the low-level features, and parameters characterizing the clusters are assigned. High-level patterns among the labels are found, and the these patterns are used to extract frames from the video according to form a content-adaptive summary of the unknown content of the video.

Description:
FIELD OF THE INVENTION  
         [0001]    This invention relates in general to computerized video processing, and more particularly, to a method and system for summarizing video content.  
         BACKGROUND OF THE INVENTION  
         [0002]    Data mining extracts information from large-scale databases and the Internet. Data mining has been applied to the analysis of market, financial, sensor, and biological data. Data mining should not be confused with pattern matching where data are searched for known patterns.  
           [0003]    Fundamentally, data mining discovers “interesting” and previously unknown patterns in data. Interesting patterns are usually defined in terms of the reoccurrence rate of a particular pattern. Because data mining does not presume any pre-defined patterns, it is frequently described as unsupervised learning.  
           [0004]    Data mining derives rules, trends, regularities and correlations from a large volume of data. Often, data mining is based on artificial intelligence (AI), memory based reasoning (MBR), association rule generation, decision trees (DT), neural analysis, statistical analysis, clustering, and time series analysis.  
           [0005]    Clustering identifies homogeneous groups of related information in data. Prior art clustering assumes that relationships among the data are known. Clustering has been studied extensively in statistics, pattern recognition, and machine learning. Examples of clustering applications include customer segmentation for marketing analysis, and identification of sub-categories of signal databases in sensed data.  
           [0006]    Clustering techniques can be broadly classified into partitional techniques and hierarchical techniques. Partitional clustering separates data into K clusters such that the data in each cluster are more similar to each other than to data in different clusters. The value of K can be assigned by a user, or iteratively determined so as to minimize the clustering criterion.  
           [0007]    Hierarchical clustering is a nested sequence of partitions. Agglomerative hierarchical clustering places data in atomic clusters and then merges the atomic clusters into larger and larger clusters until all data are in a single large cluster. Divisive hierarchical clustering reverses the process by starting with all data in one cluster and subdividing the cluster into smaller clusters, see for example, Jain et al., “ Algorithms for Clustering Data ,” Prentice Hall, 1988, Piramuthu et al., “ Comparison of SOM neutral network and hierarchical clustering methods ,” European Journal of Operational Research, 93(2):402-417, September 1996, Michaud, “ Four clustering techniques ,” FGCS Journal, Special Issue on Data Mining, 1997, and Zait et al., “ A Comparative study of clustering methods ,” FGCS Journal, Special Issue on Data Mining, 1997.  
           [0008]    Most data mining methods reduce the dimensionality of the input data. Clusters that are formed in a high-dimensional data space are not likely to be meaningful clusters because the expected average density of points anywhere in the high-dimensional data space is low. Known techniques for reducing the dimensionality of data include principal component analysis (PCA), factor analysis, singular value decomposition (SVD), and wavelets. Principal component analysis, also known as the Karhunen-Loeve expansion, finds a lower-dimensional representation that explains variances of data attributes, whereas factor analysis finds correlations among the data attributes. Jain et al., in “ Algorithms for feature selection: An evaluation, Technical report ,” Department of Computer Science, Michigan State University, East Lansing, Mich., 1996, describe a technique for image analysis.  
           [0009]    A popular data mining method used for analysis of consumer buying patterns is the identification of non-obvious associations, or association rules. An example of an obvious association is that consumers who buy baby formula also buy diapers at the same time. However, it was discovered in 1992 that beer and diapers are often purchased together in the evening hours. Such an association is a good example of a non-obvious association. Normally, one would not associate diapers and beer as strongly related purchase items because beer is usually not considered a baby formula. Such an approach has also been termed market-basket analysis.  
           [0010]    An association is defined as follows. If there is a set of n items I 1 , . . . , I n , and a transaction, e.g., a database or operation, that selects a subset of the n items, then an association between two items I i  and I j  is defined as a rule R for any transaction in both items I i  and I j  are selected into the subset. A condition of the rule R is defined as the occurrence of item I i . A result of the rule R is defined as the occurrence of the item I j . A support of the rule R is defined as a percentage of the transactions that have both items I i  and I j . A combination of the rule R is defined as the occurrence of both items I i  and I j  in the same transaction. A confidence of the rule R is defined as a ratio of the support of the combination and the support of the condition. Finally, an improvement of the rule R is defined as a ratio of the support of the rule over the product of the support of the condition I i  and the support of the result I j .  
           [0011]    An association is strong when both the support and the confidence of the association are high. For example, for a grocery store transaction, milk is strongly correlated with every other item sold so the support is high, because most transactions include milk as an item. However, for some items, such as greeting cards, the confidence is low because these are bought infrequently.  
           [0012]    Finally, the improvement of the association needs to be strong as well, because an improvement less than 1 indicates that the condition does not predict the combination with any better accuracy than by using the raw probability of the combination itself. So even if the support and confidence of the rule are high, without a corresponding improvement greater than 1, the rule offers no advantage over pure chance. Below, we describe the use of associations for “labeled clusters” of video features, instead of consumer “items.” 
           [0013]    Time series analysis correlates data values as a function of their temporal separation. For example, time series analysis has been used to discover patterns in stock prices, sales volumes, climate data, and EKG analysis. It is generally assumed that there is an underlying deterministic process that generated the time series and that that process is not random. However, time series data of real-world phenomena is often intermixed with non-deterministic data, for example, unavoidable random noise.  
           [0014]    Typically, time series are compared using a similarity measure such as the Euclidean distances, or some variation thereof. However, Euclidean distance measurements tend to be unreliable. A more robust similarity measure is based on dynamic time warping (DTW), see Berndt et al., “ Finding patterns in time series: a dynamic programming approach ,” Advances in Knowledge Discovery and Data Mining. AAAI/MIT Press, Menlo Park, Calif. pp. 229-248, 1966. DTW attempts to align time series data by selectively stretching and shrinking the time axis.  
           [0015]    Up to now, most data mining techniques have focused on textual data, numeric data and linear (one-dimensional) signals. However, a huge amount of information is now readily available in the form of multi-dimensional images, movies, and videos that have both space and time dimensions.  
           [0016]    Some prior art techniques perform a rudimentary type content analysis on videos. The most common approach trains an expert system using a set of labeled samples, hence those techniques are based on supervised learning, and not unsupervised data mining see Xu et al., “ Algorithms and Systems for Segmentation and Structure Analysis in Soccer Video ,” IEEE International Conference on Multimedia and Expo, Tokyo, Japan, Aug. 22-25, 2001, U.S. patent application Ser. No. 09/839,924 “Method and System for High-Level Structure Analysis and Event Detection in Domain Specific Videos,” filed by Xu et al., on Apr. 20, 2001, and Naphade et al., “ Probabilistic multimedia objects  ( multijects ):  A novel approach to indexing and retrieval in multimedia systems ,” Proceedings of the fifth IEEE International Conference on Image Processing, vol. 3, pp. 536-540, 1998.  
           [0017]    Prior art unsupervised video analysis techniques are mostly content neutral. For example, videos have been summarized by selecting key frames from identified segments. There, the segments are determined by detecting scene or “shot” changes, e.g., fades or sudden changes in audio volume. What the scenes depict is immaterial. The particular frame selected is usually a good representative of the other frames in the shot according to some criterion. Other techniques exploit changes in camera angles or field of view, e.g., zooming. Such content-neutral techniques have had moderate success and require supplementary content-specific techniques for semantically satisfactory performance.  
           [0018]    However, in general, the problems associated with content-based video mining are not well understood.  
           [0019]    For example, it is unclear whether well-known classification and regression trees (CART) are applicable to video mining without considerable modification. The CART method splits independent variables into small groups of data sets, and fits a constant function to the small data sets. In categorical trees, the constant function is one that takes a finite small set of values, e.g., yes and no, or low, medium, and high. In regression trees, the mean value of the response is fit to small connected data sets.  
           [0020]    Therefore, it is desired to provide a system and method for mining multi-dimensional time series data sensed from a scene, i.e., a sequence of frames acquired by a camera—a video. Video mining would be particularly useful for discovering interesting patterns in videos where an a priori model of the domain and content, such as editing models, characteristics of a news video, or patterns in a sports video, etc., are not readily available.  
         SUMMARY OF THE INVENTION  
         [0021]    A method summarizes unknown content of a video. First, low-level features of the video are selected. The video is then partitioned into segments according to the low-level features.  
           [0022]    The segments are grouped into disjoint clusters where each cluster contains similar segments. The clusters are labeled according to the low-level features, and parameters characterizing the clusters are assigned.  
           [0023]    High-level patterns among the labels are found, and the these patterns are used to extract frames from the video according to form a content-adaptive summary of the unknown content of the video. 
       
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS  
       [0024]    [0024]FIG. 1 is a flow diagram of a video mining method  100  according to the invention;  
         [0025]    [0025]FIG. 2 is a time series diagram of a golf video;  
         [0026]    [0026]FIG. 3 is a point cross-distance matrix used by the invention;  
         [0027]    [0027]FIG. 4 is a point cross-distance matrix with repeating patterns;  
         [0028]    [0028]FIG. 5 is a graph of a near-diagonal minimum cost path; and  
         [0029]    [0029]FIG. 6 is a graph of a minimum path with threshold angles. 
     
    
     DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT  
       [0030]    [0030]FIG. 1 shows the steps for a video mining method  100  according to our invention. Our invention is particularly useful for mining videos where patterns in the content are not known a priori, such as surveillance or home videos. The discovered patterns can be used for “blind” summarization of videos. By blind summarization, we mean that we do not need to know the content or genre of the video to be summarized. Our method is also useful for carefully prepared videos such as broadcast news, broadcast sports, feature films, etc. Thus, our method enables blind summarization of videos with a diverse range of variations in content and production styles.  
         [0031]    We begin with a video  101  of arbitrary, and perhaps, unknown content and production style. The video includes visual and audio data. First, we select  110  a low-level feature  102  of the content, e.g., a group of features can consist of motion activity, color, audio, texture etc. such as MPEG-7 descriptors. Mining can be performed with one or more selected features  102 , and the results  152  of each mining pass can be combined to infer  160  a higher level of understanding of the input video  101 . We use the selected feature generate a time series  200  for the video  101 .  
         [0032]    [0032]FIG. 2 is an example of the time series  200  of a video of a golf game based on motion activity. FIG. 2 plots the level of motion activity in a golf video as a function of time. Time is indicated on the x-axis  201  in terms of frame numbers, and motion activity is indicated along the y-axis  202  as the average number of pixels moved in a macro-block since a previous frame. The raw motion activity is indicated by the plot  203 . We threshold the motion activity data into high  211 , medium  212 , and low  213  levels of motion activity.  
         [0033]    We observe long stretches of low motion activity followed by an abrupt rise in motion activity, and mark the rising edge with a spike as shown. Such spikes correspond to ball hits. Up until the ball is hit, the motion activity is typically very low. During and immediately after the ball hit, the camera moves quickly to follow the ball, hence the “rising edge” of motion activity.  
         [0034]    According to our invention, motion activity in the sequence of frames of the video  101  constitutes a time series. A color histogram of the video frames is another multi-dimensional time series. Time-series data in a video can also include symbolic values such as semantic labels, e.g., MPEG-7 descriptors, and audio signals.  
         [0035]    Our method  100  measures  130  similar expressions of the low-level features based on the time series  200  of the video, e.g., high, medium, or low in the case of motion, dominant blue, green, or brown colors could be another expression. We provide a “soft” matching where small differences do not necessarily invalidate a match. We do this by data smoothing or thresholding the low-level features  102 , as described above. If multiple features are used, the time series data can be weighted. For example, in the final result, color can be given a greater weight than motion activity. Our coupling between the low-level features during the inference  160  is loose, and therefore, we prefer to apply our data mining to each of the features separately, and infer higher level patterns  161  by fusing  160  clustered data  151  obtained separately by video mining on the selected low-level features  102 .  
         [0036]    In contrast with the prior art, which only finds similar pairs at a given resolution, our matching finds  140  all possible matching pairs at all temporal resolutions in a large time series, such as the time series  200  obtained from the video.  
         [0037]    To mine for all temporal pattern in the time series S(i)  200   103 , we need multi-resolution windows of various sizes w,  
         [0038]    w: S(1:w), S(2:w+1), . . . , S(N−w+1:N).  
         [0039]    It should be noted that we do not explicitly construct the multi-resolution windows w. Instead, our windows w are implicitly defined by a cross-distance matrix  300 , and what we do is find these implicitly defined windows. This enables us to find all matches at all resolutions. Our implicit window finding technique is described in greater detail below.  
         [0040]    We measure  130  point cross-distances  300  between for the time series data  200  to find  140  minimum distances  400 , and to cluster  150  the video  101  accordingly. The problem is how to find similarities where the multi-resolution windows have different sizes.  
         [0041]    As shown in FIG. 3, we solve this problem with the point distance matrix  300 . A distance  301  between two windows  302 - 303  of size w is measured as:  
           D   w          (       x   i     ,     x   j       )       =       ∑     k   =   0       w   -   1                           (       x     i   +   k       -     x     j   +   k         )     2     .                             
 
         [0042]    Then,  
           D   1 ( x   i   ,x   j )=( x   i+k   −x   j+k ) 2 , and                  D   w          (       x   i     ,     x   j       )       =       ∑     k   =   0       w   -   1              D   1                       (       x     i   +   k       ,     x     j   +   k         )     .                 (   1   )                                 
         [0043]    [0043]FIG. 3 shows the example point distance matrix  300  where one window  301  is x i −x i+w  and another window  302  is x j −x j+w . The line  301  represents equation (1). The curves  311  and  312  represent respectively the time series  200 . That is, the same time series is along the x- and y-axis, in other words the measurement is self-correlating.  
         [0044]    The point distance matrix  300  can be searched for diagonal lines of short point cross-distances. In the representation of FIG. 3, the distances are rendered on a gray-scale where shorter distances are lighter than large distance, hence, the major diagonal where all distances are zero is white, because the measurement is self-correlated.  
         [0045]    As an advantage, the matrix  300  is not limited to any given window size w. Therefore, it is possible to find all possible diagonal paths of short distance values, where short is with respect to some threshold distance value T D . If time warping is used the path can be “near” or substantially diagonal to the main diagonal  310  in FIG. 3.  
         [0046]    As shown in FIG. 4, we perform multi-resolution analysis by sub-sampling the time series using multi-scale techniques, e.g., wavelets, adapted for our video content mining. This generates a smooth matrix  400 . Our method automatically matches across different window sizes w to reveal all repeating temporal patterns  401 - 402  in the time series.  
         [0047]    Dynamic time warping (DTW) is used to “stretch” and “compress” time, within certain limits, to allow for a good alignment between similar segments of the video having different lengths of time. By segment, we mean a sequence of frames. Dynamic programming can be used to find the time warping of the segments that give a best match. DTW finds an optimum path in the grid under certain constraints  
         (i,j), 1≦I≦N, 1≦j≦M,  
         [0048]    where N and M are the lengths of two segments, and each grid point (i, j) is a distance between the i th  and j th  points in the two segments, respectively.  
         [0049]    We find a minimum cost path between pairs of points in the point cross-distance matrix using dynamic programming. We want that path to be substantially diagonal, i.e., substantially parallel to the main diagonal  310 . in addition, we want the path to pass through low cross-distance values in the matrix, where low is defined by some threshold value T D . These paths are the white, or near white diagonal curve segments in FIGS. 3 and 4.  
         [0050]    A possible definition of the minimum cost is an average of the cross-distance values along the path. We also put some constraints on the allowed paths, i.e., the path  500  preserves an orientation in the diagonal direction, see FIG. 5. One possible set of constraints is that, at each step along the path can move down one, right one, or diagonally, as shown.  
         [0051]    Additionally as shown in FIG. 6, a threshold angle between the diagonal, and the line drawn between the two end points of the path, should be less than a 0 , where 0≦a≦45°. Such path cost criteria and constraints can be formulated by dynamic programming to find the minimum cost valid path between two points in the point cross-distance matrix.  
         [0052]    A valid path thus obtained, even if it is not exactly diagonal, specifies a dynamic time warping of two corresponding sub-sequences the time series. Hence, we find the appropriate time warping for a good match between two sub-sequences by using dynamic programming, and find the minimum cost path between two points in the cross-distance matrix.  
         [0053]    Dynamic programming allows us to find the minimum cost path between two given points in the matrix. We are interested in finding the minimum cost paths between all possible pairs of points in the matrix, and select the ones that have a cost below a given threshold.  
         [0054]    A brute force way of doing this is by running the dynamic programming process for each possible pair of points. Because the cross-distance matrix is symmetric, i.e., the distance between the i th  and j th  samples of the time series is equal to the distance between the j th  and i th  samples, we only need to process the upper half of the matrix, where there are only N 2 /2 points, and N 4 /4 point pairs. However, the number of processing steps can be reduced to increase the efficiency of our method.  
         [0055]    First as shown in FIG. 6, we require the angle between the diagonal and the line passing through the two end points of the path to be less then a 0 . Then, for each point, we find the minimum cost path to the points that are located between the lines at +a 601 and −a 602 degrees from the diagonal  603 . Furthermore, we put the constraint that all the points on a path should have a value lower than the threshold T. In this case, we can threshold the whole matrix and find the minimum cost paths only between the set of points that are above the threshold.  
         [0056]    After the minimum cost paths between all such points have been found, we merge shorter paths with end points close to each other into a longer path. We also merge paths where one is a superset of another. We eliminate paths where the Euclidean distance between the two end points is shorter then a certain length. The remaining set of paths provides us with all pairs of similar sub-sequences in the video at multiple resolutions.  
         [0057]    In the prior art, the similarity using dynamic time warping (e.g., by finding a minimum cost path in the cross-distance matrix using dynamic programming) is done for querying a given time sequence pattern in a larger time sequence, see Park et al., “ Efficient search for similar subsequences of different lengths in sequence databases , International Conference on Data Engineering (ICDE), pp. 23-32, 2000.  
         [0058]    Our technique can also be used for finding a good alignment between two sequences in the context of speech analysis, see Sakoe et al. “ Dynamic programming algorithm optimization for spoken word recognition ,” IEEE Trans. Acoust., Speech, Signal Process., ASSP 26, pp. 43-49, 1978, and gene and protein sequence analysis, see Aach et al., “ Aligning gene expression time series with time warping algorithms ,” Bioinformatics, 17:495-508, 2001. However, those methods find only one path with a given starting point, in a given cross-distance matrix, in contrast, we find all paths.  
         [0059]    In the prior art, self-similarity of sub-sequences in time series is usually computed using a fixed window size w, and computing the cross-distances between shifted windows on the original sequence, see Agrawal et al., “ Efficient Similarity Search in Sequence Databases ,” Proc. of the 4 th  Int&#39;l Conference on Foundations of Data Organization and Algorithms, and “ Lecture Notes in Computer Science,”  730, Springer Verlag, p., 69-84.  
         [0060]    Other prior art use of cross-distance matrix is in the form of dot-plots where the matrix elements are either 1 or 0, indicating an exact match or no match. They have been used for qualitative analysis and as visual tools, see Church et al., “ Dotplot: A program for exploring self - similarity in millions of lines of text and code ,” Journal of Computational and Graphical Statistics, 2(2):153-174, 1993., or for segmenting self-similar regions along the diagonal but not for automatically finding pairs of similar sub-sequences, see Jeffry, “ An Automatic Method of Finding Topic Boundaries ” Proceedings of the 32 nd  Annual Meeting of the Association for Computational Linguistics, 1994. Our method can be used for any of these applications.  
         [0061]    A Hough transform could be applied to merge multiple short paths into curves. The Hough transform isolates features of a particular shape within the matrix  400 . We could use the Hough transform because a simple analytic description of the features is not possible. As an advantage, the Hough transform is tolerant to gaps in feature boundary descriptions and is relatively unaffected by noise in the data. In addition, the Hough transform is particularly useful for discovering a global description of the features, where the number of solution classes is not known a priori, as is the case here.  
         [0062]    Our motivation for using the Hough transforms is that each input distance feature indicates its contribution to a globally consistent pattern. We implement the Hough transform by quantizing the feature space into finite intervals or accumulator cells that reveal a discretized path as the accumulator cells which lie along this path are incremented. Resulting peaks in the accumulator array represent strong evidence that a corresponding path exists in the feature space. We use the Hough transform to identify the paths which best fits a set of given edges.  
         [0063]    Of course it should be understood that other techniques for finding matching segments using self-correlation of the time series could be used. For example, a dot product could be used. In this case the magnitude of the product is indicative of the level of similarity. For multi-dimensional time series such as color histograms of consecutive frames, histogram intersection could be used.  
         [0064]    After we find the matching windows using DTW, we group and label  150  similar segments into clusters  151 . By a segment we mean a sequence of frames in the video that directly corresponds to a window having similar features. Thus, the identification of the similar segments using the time series data essentially allows us to partition the video and group similar segments into clusters.  
         [0065]    We use the term “label” and “item,” as defined above for associations, equivalently. When we refer to clusters, we imply that the clusters are labeled, e.g., a cluster of high motion activity frames, or a cluster of loud noise in the sound track of the video. Using associations and fusion of labels  152  obtained using different features allows us to infer  160  high-level patterns  161  in the clusters  151 . These patterns can then be used for blind summarization  170  of the video  101  into a summary  171 . The summarization essentially extracts selected frames of the video according to the high-level patterns  161 .  
         [0066]    In step  160 , we find associations between labels of the clusters. One type of association looks for “labels” that correlated in time. The correlation can either be simultaneous, or time shifted, e.g., a lot of motion and loud noise signals an “action” event in a entertainment video, or a lot of motion later followed by applause and cheering signals a “scoring” event in a sports video.  
         [0067]    We find associations between labels as follows. The label for each cluster is considered equivalent to an “item” as stated above. Thus, we generated a condition including the occurrence of the label L i  and a result including the occurrence of a label L j . In this case, every point on the time axis has a corresponding transaction, which includes labels corresponding to more than one of the video features  102 .  
         [0068]    For example, we could have two sets of labels, the first one corresponding to a description of motion activity as high, medium or low and the second one related to audio semantic classes where the label would indicate membership in an audio class such as applause, cheering, music, etc. Then, we can find an association between high motion activity and applause/cheering in a sports video. Note that even if more sophisticated labels are used, the association can be found through a straightforward computation. It is also possible to find compound associations between combinations of labels.  
         [0069]    Then, a strong associations can help us find corresponding common and uncommon patterns in the video  101 , because the more common the pattern, the higher the support.  
         [0070]    Then, the summary  171  of the video  101  contains a combination of the common and uncommon events depending on the needs of the user. In one extreme, the summary  171  contains rare events with strong associations. In another extreme, the summary contains common events with strong associations.  
         [0071]    Therefore, the clustering  150  begins by clustering all similar segments based on the distance metric as described above. Partially overlapping segments are divided so that they either have an identical overlap, or none at all. Pairs of clusters can be merged using an agglomerative procedure to form bigger clusters. We define a set S to contain all segments that are in at least one of the similar pairs of clusters. Then, the set S c ∪S is the entire video  101 , and the set S c  is the complement of the set S. The clusters are labeled, e.g., A, B, C, . . . and A∪B∪C . . . =S. The set S c  can be considered a “junk” cluster that is not as “meaningful” with respect to the labels A, B, and C, etc.  
         [0072]    Thus, the clustering  150  produces the set S of non-overlapping segments of various lengths, and their mutual distances. Each cluster  151  has the following associated parameters: cluster compactness, i.e., how similar are the segments in the cluster; number of segments in the cluster; total length of the segments (in frames or time) in the cluster; and average distance between the closest points of the segments which indicates the spreading of the segments in the entire video.  
         [0073]    Each segment in a cluster has the following parameters: average distance to other cluster center, which indicates how representative the segment is of the cluster in which it is contained; and its length (frames or time).  
         [0074]    Then, a summarization cost function C  172  can trade-off an absolute difference between a required summary length, a total length of a set R of selected segment to be included in the summary  171 , (i.e., R⊂S), an average of the distances between each segment in S and a closest segment in a set R. This indicates how well the set R (summary  171 ) represents the set S, which, of course, is the entire video  101 . We can add a term to favor compactness of R in time, or the opposite. The summary  171  then is the subset R of set S that minimizes the cost function  172 .  
         [0075]    The summary can then be used for new modalities of video control such as “smart” fast-forward and reverse, and instant repositioning in the face of no a priori domain knowledge.  
         [0076]    It is to be understood that various other adaptations and modifications may be made within the spirit and scope of the invention. Therefore, it is the object of the appended claims to cover all such variations and modifications as come within the true spirit and scope of the invention.