Heller B W, Veltink P H, Rijkhoff N J, Rutten W L, Andrews B J
Bioengineering Unit, University of Strathclyde, Glasgow, Scotland.
Biol Cybern. 1993;69(4):327-35. doi: 10.1007/BF00203129.
One symbolic (rule-based inductive learning) and one connectionist (neural network) machine learning technique were used to reconstruct muscle activation patterns from kinematic data measured during normal human walking at several speeds. The activation patterns (or desired outputs) consisted of surface electromyographic (EMG) signals from the semitendinosus and vastus medialis muscles. The inputs consisted of flexion and extension angles measured at the hip and knee of the ipsilateral leg, their first and second derivatives, and bilateral foot contact information. The training set consisted of data from six trials, at two different speeds. The testing set consisted of data from two additional trials (one at each speed), which were not in the training set. It was possible to reconstruct the muscular activation at both speeds using both techniques. Timing of the reconstructed signals was accurate. The integrated value of the activation bursts was less accurate. The neural network gave a continuous output, whereas the rule-based inductive learning rule tree gave a quantised activation level. The advantage of rule-based inductive learning was that the rules used were both explicit and comprehensible, whilst the rules used by the neural network were implicit within its structure and not easily comprehended. The neural network was able to reconstruct the activation patterns of both muscles from one network, whereas two separate rule sets were needed for the rule-based technique. It is concluded that machine learning techniques, in comparison to explicit inverse muscular skeletal models, show good promise in modelling nearly cyclic movements such as locomotion at varying walking speeds.(ABSTRACT TRUNCATED AT 250 WORDS)
使用一种符号式(基于规则的归纳学习)和一种联结主义(神经网络)机器学习技术,从在几种速度下正常人类行走过程中测量的运动学数据重建肌肉激活模式。激活模式(或期望输出)由半腱肌和股内侧肌的表面肌电图(EMG)信号组成。输入包括同侧腿的髋部和膝部测量的屈伸角度、它们的一阶和二阶导数以及双侧足部接触信息。训练集由来自六个试验、两种不同速度的数据组成。测试集由来自另外两个试验(每种速度各一个)的数据组成,这些数据不在训练集中。使用这两种技术都能够在两种速度下重建肌肉激活。重建信号的时间是准确的。激活脉冲的积分值不太准确。神经网络给出连续输出,而基于规则的归纳学习规则树给出量化的激活水平。基于规则的归纳学习的优点是所使用的规则既明确又易于理解,而神经网络所使用的规则隐含在其结构中且不易理解。神经网络能够从一个网络重建两块肌肉的激活模式,而基于规则的技术需要两个单独的规则集。得出的结论是,与明确的逆肌肉骨骼模型相比,机器学习技术在对几乎周期性运动(如不同行走速度下的运动)进行建模方面显示出良好的前景。(摘要截短为250字)
