Dryad
Published November 19, 2015 | Version v1
Dataset Open

Data from: Constructing predictive models of human running

Authors/Creators

  • 1. Technical University of Darmstadt
  • 2. University of Michigan-Ann Arbor
  • 3. Cornell University
  • 4. Ilmenau University of Technology

Description

Running is an essential mode of human locomotion, during which ballistic aerial phases alternate with phases when a single foot contacts the ground. The spring-loaded inverted pendulum (SLIP) provides a starting point for modelling running, and generates ground reaction forces that resemble those of the centre of mass (CoM) of a human runner. Here, we show that while SLIP reproduces within-step kinematics of the CoM in three dimensions, it fails to reproduce stability and predict future motions. We construct SLIP control models using data-driven Floquet analysis, and show how these models may be used to obtain predictive models of human running with six additional states comprising the position and velocity of the swing-leg ankle. Our methods are general, and may be applied to any rhythmic physical system. We provide an approach for identifying an event-driven linear controller that approximates an observed stabilization strategy, and for producing a reduced-state model which closely recovers the observed dynamics.

Notes

Positions of the markers (motion capture)
This document indicates the location of the markers on each subject, which were used to record the kinematics.
markerpos.pdf
Experimental data subject 1: 1/6
Force and kinematic recordings from subject 1, dataset 1 of 6 consecutive recording sequences.
subj1_r1.zip
Experimental data subject 2: 2/6
Force and kinematic recordings from subject 2, dataset 2 out of 6 consecutive recording sequences.
subj2_r2.zip
Experimental data subject 1: 2/6
Force and kinematic recordings from subject 1, dataset 2 out of 6 consecutive recording sequences.
subj1_r2.zip
Experimental data subject 1: 3/6
Force and kinematic recordings from subject 1, dataset 3 out of 6 consecutive recording sequences.
subj1_r3.zip
Experimental data subject 1: 4/6
Force and kinematic recordings from subject 1, dataset 4 out of 6 consecutive recording sequences.
subj1_r4.zip
Experimental data subject 1: 5/6
Force and kinematic recordings from subject 1, dataset 5 out of 6 consecutive recording sequences.
subj1_r5.zip
Experimental data subject 1: 6/6
Force and kinematic recordings from subject 1, dataset 6 out of 6 consecutive recording sequences.
subj1_r6.zip
Experimental data subject 2: 1/6
Force and kinematic recordings from subject 2, dataset 1 out of 6 consecutive recording sequences.
subj2_r1.zip
Experimental data subject 2: 3/6
Force and kinematic recordings from subject 2, dataset 3 out of 6 consecutive recording sequences.
subj2_r3.zip
Experimental data subject 2: 4/6
Force and kinematic recordings from subject 2, dataset 4 out of 6 consecutive recording sequences.
subj2_r4.zip
Experimental data subject 2: 5/6
Force and kinematic recordings from subject 2, dataset 5 out of 6 consecutive recording sequences.
subj2_r5.zip
Experimental data subject 2: 6/6
Force and kinematic recordings from subject 2, dataset 6 out of 6 consecutive recording sequences.
subj2_r6.zip
Experimental data subject 3: 1/6
Force and kinematic recordings from subject 3, dataset 1 out of 6 consecutive recording sequences. Note: record #5 is missing (corrupted data). We did not relabel record #6, to indicate that there is a lack of data of about 4 minutes duration between #4 and #6.
subj3_r1.zip
Experimental data subject 3: 2/6
Force and kinematic recordings from subject 3, dataset 1 out of 5 recording sequences. Note: record #5 is missing (corrupted data). We did not relabel record #6, to indicate that there is a lack of data of about 4 minutes duration between #4 and #6.
subj3_r2.zip
Experimental data subject 3: 3/6
Force and kinematic recordings from subject 3, dataset 3 out of 5 recording sequences. Note: record #5 is missing (corrupted data). We did not relabel record #6, to indicate that there is a lack of data of about 4 minutes duration between #4 and #6.
subj3_r3.zip
Experimental data subject 3: 4/6
Force and kinematic recordings from subject 3, dataset 4 out of 5 recording sequences. Note: record #5 is missing (corrupted data). We did not relabel record #6, to indicate that there is a lack of data of about 4 minutes duration between #4 and #6.
subj3_r4.zip
Experimental data subject 3: 6/6
Force and kinematic recordings from subject 3, dataset 5 out of 5 recording sequences. Note: record #5 is missing (corrupted data). We did not relabel record #6, to indicate that there is a lack of data of about 4 minutes duration between #4 and #6.
subj3_r6.zip
Experimental data subject 7: 1/6
Force and kinematic recordings from subject 7, dataset 1 out of 6 consecutive recording sequences.
subj7_r1.zip
Experimental data subject 7: 2/6
Force and kinematic recordings from subject 7, dataset 2 out of 6 consecutive recording sequences.
subj7_r2.zip
Experimental data subject 7: 3/6
Force and kinematic recordings from subject 7, dataset 3 out of 6 consecutive recording sequences.
subj7_r3.zip
Experimental data subject 7: 4/6
Force and kinematic recordings from subject 7, dataset 4 out of 6 consecutive recording sequences.
subj7_r4.zip
Experimental data subject 7: 5/6
Force and kinematic recordings from subject 7, dataset 5 out of 6 consecutive recording sequences.
subj7_r5.zip
Experimental data subject 7: 6/6
Force and kinematic recordings from subject 7, dataset 6 out of 6 consecutive recording sequences.
subj7_r6.zip
info
A description of the individual files
SLIP parameter
This is a collection of SLIP parameter, which yield in a forward simulation the same sequence of apex states as observed in the experiment. For details see manuscript and references therein.
slip_parameter.zip

Files

info.txt

Files (1.8 GB)

Name Size Download all
md5:33a2c5637fc0f448e8f716554f2d06ba
3.7 kB Preview Download
md5:d7fdacabbe6bcacf7b7265f29fefb215
83.5 kB Preview Download
md5:297fa488650b46182854f95293f2a56e
2.6 MB Preview Download
md5:7109f985f6cb0b7f6c81ff45c426885c
77.4 MB Preview Download
md5:d4ea0ac961c5fe71a31d0c245d4c7ea0
77.4 MB Preview Download
md5:d6c5bf5bc3bd2bdc4a394dcdd1b5590e
77.3 MB Preview Download
md5:af026b9096ffab00df1ed843be97dae0
77.1 MB Preview Download
md5:d5cc8e4021387989c981c849ea74138a
77.3 MB Preview Download
md5:2f8ac418bfceef4449fde9dc9248b47d
77.2 MB Preview Download
md5:295b92fbe7b61b61c1c4e74b44117337
77.4 MB Preview Download
md5:21829d6a603dd88986d025e36d5b8e8f
77.3 MB Preview Download
md5:a15404db57abd50a88c3af40757a44bb
77.3 MB Preview Download
md5:617f2aff9c86c079ca6c25e81cb6aea9
77.4 MB Preview Download
md5:0020478acb6e9af3acd9b0d416be0780
77.5 MB Preview Download
md5:776d51bd7b8093e2978957628e29900d
77.4 MB Preview Download
md5:e423e22a9702ea497440e25a6490c482
77.8 MB Preview Download
md5:5a881131dbb70785f3d93020d49d9c0a
77.5 MB Preview Download
md5:53b08a8c30dc517876a18ef55699d8af
77.6 MB Preview Download
md5:a1fd9e7c19eaf6c4a08bcfe9019b5d1d
78.1 MB Preview Download
md5:4546ac6e9916dd1ffbdfd9e3899b9126
77.8 MB Preview Download
md5:870e564a4f94cfc2e672b4a202dee542
77.1 MB Preview Download
md5:47e3f75056d6d60d68b5dc87ce1dfe9d
76.8 MB Preview Download
md5:00000a48254279ef9b06dacf905a5e5e
76.9 MB Preview Download
md5:d3adcf82275f9e592cbf8a60e1237527
76.9 MB Preview Download
md5:fea22c8950be6cf0620ae3f1e25c9f5e
76.9 MB Preview Download
md5:4c3a54ed3967fc3f1a649d44138897fc
76.8 MB Preview Download

Additional details

Related works

Is cited by
10.1098/rsif.2014.0899 (DOI)