Selecting and presenting representative frames for video previews

What is claimed is: 1. A computer-implemented method for selecting representative frames for videos, comprising: receiving a video including a set of frames; identifying a set of features for each of the frames of the video, wherein the set of features includes frame-based features and semantic features, and wherein each of the semantic features for a frame is identified by (i) transmitting a designation of the frame associated with the frame-based features to a plurality of semantic classifiers, (ii) receiving, from each of the plurality of semantic classifiers, a likelihood of a semantic concept being depicted in the frame of the video, and (iii) assigning a label corresponding to the semantic concept to the frame of the video based on the likelihood of the semantic concept being depicted in the frame of the video; generating a set of video segments for the video, each video segment including a chronological subset of frames from the video, and each frame associated with at least one of the semantic features; generating, for each video segment in the set of video segments, a score for each frame of the subset of frames of the video segment based at least on the semantic features; selecting a plurality of representative frames of the video, wherein each representative frame for each video segment in the set of video segments is selected based on the scores for the frames in the video segment, the representative frame representing and summarizing the video segment; and generating a summarized video that combines at least a portion of the plurality of representative frames of the video. 2. The method of claim 1 , further comprising generating a segment table for the video, the segment table storing the representative frames for the video segments of the video and the set of semantic concepts associated with each of the representative frames. 3. The computer-implemented method of claim 1 , wherein the frame-based features comprise at least one of: a visual feature comprising at least one from the group consisting of a color histogram, a histogram of oriented gradients, color-differencing of a frame with adjacent frames, motion features, or feature tracking, and; an audio feature comprising at least one from the group consisting of a volume, an audio spectrogram, a speech-no-speech indicator, or a stabilized auditory image. 4. The computer-implemented method of claim 1 , wherein the label corresponds to an entity or free text. 5. The computer-implemented method of claim 1 , wherein the step of generating the set of video segments comprises: analyzing the frame-based features to determine a set of shot boundaries within the video; wherein a shot includes a set of sequential frames and a shot boundary indicates a frame between neighboring shots. 6. The computer-implemented method of claim 5 , wherein the step of determining the set of shot boundaries comprises: applying a classifier to frames associated with frame-based features to determine whether a frame is a shot boundary; wherein the classifier is trained using labeled shot boundaries as a positive feature set and frames near the shot boundaries as a hard-negative training set, and wherein the frame-based features comprise color differences with adjacent frames, motion features, audio volume, and audio speech detection. 7. The computer-implemented method of claim 5 , wherein the step of determining the set of shot boundaries comprises: analyzing a coherence of the frame-based features; wherein the coherence measures similarity of frame-based features in a predetermined temporal segment, and wherein the similarity provides a distance measure for segmenting the video. 8. The computer-implemented method of claim 5 , wherein the step of determining the set of shot boundaries comprises: tracking the frame-based features across the series of frames of the video; and wherein a frame is determined as a shot boundary when a change of frame-based features between the frame and neighboring frames is greater than a threshold. 9. The computer-implemented method of claim 1 , wherein the score comprises a semantic score and the step of generating the semantic score for the frame comprises: identifying a set of semantic concepts for a video segment containing the frame by comparing each semantic feature generated for the chronological subset of frames included in the video segment to a threshold, each semantic concept of the set having the corresponding semantic feature greater than the threshold; for each semantic concept of the set, determining a frame-level score for each frame of the chronological subset of frames in the video segment by determining an amount the semantic concept being present in the frame compared to a reference value; and determining the semantic score for the frame by aggregating the frame-level scores of the frames in the segment. 10. The computer-implemented method of claim 1 , wherein the step of generating the score for the each frame comprises combining semantic concepts and corresponding likelihood in the frame. 11. The computer-implemented method of claim 1 , wherein the score combines a semantic score and an aesthetic score and the step of generating the score for the each frame comprises: calculating the semantic score based on the determined semantic features; calculating the aesthetic score using a set of quality measures comprising at least one from the group consisting of sharpness, an amount of motion, distance from a segment boundary, and photo quality; and combining the semantic score and the aesthetic score. 12. The computer-implemented method of claim 1 , further comprising presenting the representative frame of a video segment responsive to receiving a request for the video segment. 13. A non-transitory computer-readable storage medium comprising computer program instructions executable by a processor, the computer program instructions comprising: receiving a video including a set of frames; identifying a set of features for each of the frames of the video, wherein the set of features includes frame-based features and semantic features, and wherein each of the semantic features for a frame is identified by (i) transmitting a designation of the frame associated with the frame-based features to a plurality of semantic classifiers, (ii) receiving, from each of the plurality of semantic classifiers, a likelihood of a semantic concept being depicted in the frame of the video, and (iii) assigning a label corresponding to the semantic concept to the frame of the video based on the likelihood of the semantic concept being depicted in the frame of the video; generating a set of video segments for the video, each video segment including a chronological subset of frames from the video, and each frame associated with at least one of the semantic features; generating, for each video segment in the set of video segments, a score for each frame of the subset of frames of the video segment based at least on the semantic features; selecting a plurality of representative frames of the video, wherein each representative frame for each video segment in the set of video segments is selected based on the scores for the frames in the video segment, the representative frame representing and summarizing the video segment; and generating a summarized video that combines at least a portion of the plurality of representative frames of the video. 14. The non-transitory computer-readable storage medium of claim 13 , wherein the computer program instructions further comprise generating a segment table for the video, the segment table storing the repre