Javascript must be enabled to continue!
Robustness of Connectionist Swimming Controllers Against Random Variation in Neural Connections
View through CrossRef
The ability to achieve high swimming speed and efficiency is very important to both the real lamprey and its robotic implementation. In previous studies, we used evolutionary algorithms to evolve biologically plausible connectionist swimming controllers for a simulated lamprey. This letter investigates the robustness and optimality of the best-evolved controllers as well as the biological controller hand-crafted by Ekeberg.Comparing cases of random variation in intrasegmental or intersegmental weights against each controller allows estimates of robustness to be made. We conduct experiments on the controllers' robustness at the excitation level, which corresponds to either the maximum swimming speed or efficiency by randomly varying the segmental connection weights and on some occasions also the intersegmental couplings, through varying noise ranges. Interestingly, although the swimming performance (in terms of maximum speed and efficiency) of the Ekeberg biological controller is not as good as that of the artificially evolved controllers, it is relatively robust against noise in the neural networks. This suggests that the natural evolutions have evolved a swimming controller that is good enough to survive in the real world. Our findings could inspire neurobiologists to conduct real physiological experiments to gain a better understanding on how neural connectivity affects behavior. The results can also be applied to control an artificial lamprey in simulation and possibly also a robotic one.
Title: Robustness of Connectionist Swimming Controllers Against Random Variation in Neural Connections
Description:
The ability to achieve high swimming speed and efficiency is very important to both the real lamprey and its robotic implementation.
In previous studies, we used evolutionary algorithms to evolve biologically plausible connectionist swimming controllers for a simulated lamprey.
This letter investigates the robustness and optimality of the best-evolved controllers as well as the biological controller hand-crafted by Ekeberg.
Comparing cases of random variation in intrasegmental or intersegmental weights against each controller allows estimates of robustness to be made.
We conduct experiments on the controllers' robustness at the excitation level, which corresponds to either the maximum swimming speed or efficiency by randomly varying the segmental connection weights and on some occasions also the intersegmental couplings, through varying noise ranges.
Interestingly, although the swimming performance (in terms of maximum speed and efficiency) of the Ekeberg biological controller is not as good as that of the artificially evolved controllers, it is relatively robust against noise in the neural networks.
This suggests that the natural evolutions have evolved a swimming controller that is good enough to survive in the real world.
Our findings could inspire neurobiologists to conduct real physiological experiments to gain a better understanding on how neural connectivity affects behavior.
The results can also be applied to control an artificial lamprey in simulation and possibly also a robotic one.
Related Results
MOSAIC for Multiple-Reward Environments
MOSAIC for Multiple-Reward Environments
Reinforcement learning (RL) can provide a basic framework for autonomous robots to learn to control and maximize future cumulative rewards in complex environments. To achieve high ...
Ankle joint flexibility affects undulatory underwater swimming speed
Ankle joint flexibility affects undulatory underwater swimming speed
The movement of undulatory underwater swimming (UUS), a swimming technique adapted from whales, is mainly limited by human anatomy. A greater ankle joint flexibility could improve ...
Bicomplex Projection Rule for Complex-Valued Hopfield Neural Networks
Bicomplex Projection Rule for Complex-Valued Hopfield Neural Networks
A complex-valued Hopfield neural network (CHNN) with a multistate activation function is a multistate model of neural associative memory. The weight parameters need a lot of memory...
Watermarking System for Medical Images Using Optimization Algorithm
Watermarking System for Medical Images Using Optimization Algorithm
One of the main methods used to provide security for medical records when exchanging these records through open networks is digital watermarking. In order to preserve the privacy o...
Detection of whale calls in noise: Performance comparison between a beluga whale, human listeners, and a neural network
Detection of whale calls in noise: Performance comparison between a beluga whale, human listeners, and a neural network
This article examines the masking by anthropogenic noise of beluga whale calls. Results from human masking experiments and a software backpropagation neural network are compared to...
The Fastskin Revolution: From Human Fish to Swimming Androids
The Fastskin Revolution: From Human Fish to Swimming Androids
The story of fastskin swimsuits reflects some of the challenges facing the impact of technology in postmodern culture. Introduced in 1999 and ratified for the Sydney 2000 Olympic G...
A Comparison of Fat Utilization during Exercise: Walking and Swimming
A Comparison of Fat Utilization during Exercise: Walking and Swimming
Women, considering swimming as a form of exercise to lose weight, have been discouraged from doing so, since researchers suggest that swimming does not burn fat as efficiently as l...
A Neural Model of Olfactory Sensory Memory in the Honeybee's Antennal Lobe
A Neural Model of Olfactory Sensory Memory in the Honeybee's Antennal Lobe
We present a neural model for olfactory sensory memory in the honeybee's antennal lobe. To investigate the neural mechanisms underlying odor discrimination and memorization, we exp...