Predicting lower limb motion intent is vital for controlling exoskeleton
robots and prosthetic limbs. Surface electromyography (sEMG) attracts
increasing attention in recent years as it enables ahead-of-time prediction of
motion intentions before actual movement. However, the estimation performance
of human joint trajectory remains a challenging problem due to the inter- and
intra-subject variations. The former is related to physiological differences
(such as height and weight) and preferred walking patterns of individuals,
while the latter is mainly caused by irregular and gait-irrelevant muscle
activity. This paper proposes a model integrating two gait cycle-inspired
learning strategies to mitigate the challenge for predicting human knee joint
trajectory. The first strategy is to decouple knee joint angles into motion
patterns and amplitudes former exhibit low variability while latter show high
variability among individuals. By learning through separate network entities,
the model manages to capture both the common and personalized gait features. In
the second, muscle principal activation masks are extracted from gait cycles in
a prolonged walk. These masks are used to filter out components unrelated to
walking from raw sEMG and provide auxiliary guidance to capture more
gait-related features. Experimental results indicate that our model could
predict knee angles with the average root mean square error (RMSE) of
3.03(0.49) degrees and 50ms ahead of time. To our knowledge this is the best
performance in relevant literatures that has been reported, with reduced RMSE
by at least 9.5%