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Adapting Wavelet Compression to Human Motion Capture Clips Philippe Beaudoin 1 Pierre Poulin 1 Michiel van de Panne 2 1 Université de Montréal, LIGUM 2 University of British Columbia, Imager
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Adapting Wavelet Compression to Human Motion Capture Clips Beaudoin, Poulin, van de Panne – Graphics Interface 2007 2 A need for compression? Motion capture is very popular Motion capture rapidly produces huge collections of data Escalating cost of the memory hierarchy (ie. Martin Walker talk) Lossy compression
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Adapting Wavelet Compression to Human Motion Capture Clips Beaudoin, Poulin, van de Panne – Graphics Interface 2007 3 What is a good compression? Depends on the application We aim for: –Small cache footprint –Access to subset of joint data –Accurate foot placement –Independent motion clips Best ratio may not be the target
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Adapting Wavelet Compression to Human Motion Capture Clips Beaudoin, Poulin, van de Panne – Graphics Interface 2007 4 Which kind of compression? Joint correlation –2:1 up to 4:1 (PCA) Joint + temporal coherence –Cannot access individual signals –30:1 up to 35:1 [Arikan 06] Temporal coherence alone –35:1 (this work) –Access to subset of joint data –Low computational requirements
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Adapting Wavelet Compression to Human Motion Capture Clips Beaudoin, Poulin, van de Panne – Graphics Interface 2007 5 Preliminary details… A pose is… –Root position (3 signals) –Euler angles of joints (59 signals) Motion is sampled at 120 hz No preprocessing or format conversion before compression
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Adapting Wavelet Compression to Human Motion Capture Clips Beaudoin, Poulin, van de Panne – Graphics Interface 2007 6 Standard wavelet compression Cubic interpolating bi-orthogonal wavelet basis [Sweldens 98] Not specially targeted to motion capture
![Adapting Wavelet Compression to Human Motion Capture Clips Beaudoin, Poulin, van de Panne – Graphics Interface Standard wavelet compression Cubic interpolating bi-orthogonal wavelet basis [Sweldens 98] Not specially targeted to motion capture](http://images.slideplayer.com/33/8224434/slides/slide_6.jpg "Adapting Wavelet Compression to Human Motion Capture Clips Beaudoin, Poulin, van de Panne – Graphics Interface Standard wavelet compression Cubic interpolating bi-orthogonal wavelet basis [Sweldens 98] Not specially targeted to motion capture")
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Adapting Wavelet Compression to Human Motion Capture Clips Beaudoin, Poulin, van de Panne – Graphics Interface 2007 7 Standard wavelet compression Wavelet transform 62 signals Keep the largest coefficients from all the transformed signals Yield vector w i (1 ≤ i ≤ 62) counting how many coefficients are kept for each signal
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Adapting Wavelet Compression to Human Motion Capture Clips Beaudoin, Poulin, van de Panne – Graphics Interface 2007 8 Vector w i
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Adapting Wavelet Compression to Human Motion Capture Clips Beaudoin, Poulin, van de Panne – Graphics Interface 2007 9 Optimized coefficient selection w i minimizes RMS error in the DOF Quality depends much more on positional distortion Optimally redistribute coefficients? –Too costly!
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Adapting Wavelet Compression to Human Motion Capture Clips Beaudoin, Poulin, van de Panne – Graphics Interface 2007 10 Optimized coefficient selection Motion capture data is hierarchical Build vector m i that favors some signals more than others Fixed choice for m i ? Bad! –Depends on complexity of signals –Depends on the poses
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Adapting Wavelet Compression to Human Motion Capture Clips Beaudoin, Poulin, van de Panne – Graphics Interface 2007 11 Start with m i = w i
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Adapting Wavelet Compression to Human Motion Capture Clips Beaudoin, Poulin, van de Panne – Graphics Interface 2007 12 Randomly select i reduce m i
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Adapting Wavelet Compression to Human Motion Capture Clips Beaudoin, Poulin, van de Panne – Graphics Interface 2007 13 Find optimal j increase m j Repeat…
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Adapting Wavelet Compression to Human Motion Capture Clips Beaudoin, Poulin, van de Panne – Graphics Interface 2007 14 Inverse kinematics correction Problem: Noticeable sliding feet Change distortion metric? –Assumption breaks down, difficult to find a good m i Instead, add positional channels for the feet, use IK
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Adapting Wavelet Compression to Human Motion Capture Clips Beaudoin, Poulin, van de Panne – Graphics Interface 2007 15 Inverse kinematics correction Signals encode difference between compressed position and true feet position Wavelet compress these signals independently
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Adapting Wavelet Compression to Human Motion Capture Clips Beaudoin, Poulin, van de Panne – Graphics Interface 2007 16 Final details… Quantize to 16 bits Run-length encode 0s Optionally use lempel-ziv independently on each clip
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Adapting Wavelet Compression to Human Motion Capture Clips Beaudoin, Poulin, van de Panne – Graphics Interface 2007 17 Results Tested on 1 sec. to 45 sec. clips Compression ≈ 300 ms/frame Decompression ≈ 30 μs/frame(no IK) ≈ 300 μs/frame(with IK)
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Adapting Wavelet Compression to Human Motion Capture Clips Beaudoin, Poulin, van de Panne – Graphics Interface 2007 18 Video
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Adapting Wavelet Compression to Human Motion Capture Clips Beaudoin, Poulin, van de Panne – Graphics Interface 2007 19 Conclusion Tractable coefficient search space adapted to motion capture data Fast decompression Access to subset of joints Independent clips 35:1 compression ratio
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Adapting Wavelet Compression to Human Motion Capture Clips Beaudoin, Poulin, van de Panne – Graphics Interface 2007 20 Future Work Metric for perceived quality in a motion capture animation Explore large-scale redundancies (see our technical report) Level-of-detail streaming
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Adapting Wavelet Compression to Human Motion Capture Clips Beaudoin, Poulin, van de Panne – Graphics Interface 2007 21 Questions?
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