TY - JOUR
T1 - Managing safety of the human on the factory floor
T2 - a computer vision fusion approach
AU - Humphries, Jacqueline
AU - Van de Ven, Pepijn
AU - Amer, Nehal
AU - Nandeshwar, Nitin
AU - Ryan, Alan
N1 - Publisher Copyright:
© 2024, Emerald Publishing Limited.
PY - 2024/8/7
Y1 - 2024/8/7
N2 - Purpose: Maintaining the safety of the human is a major concern in factories where humans co-exist with robots and other physical tools. Typically, the area around the robots is monitored using lasers. However, lasers cannot distinguish between human and non-human objects in the robot’s path. Stopping or slowing down the robot when non-human objects approach is unproductive. This research contribution addresses that inefficiency by showing how computer-vision techniques can be used instead of lasers which improve up-time of the robot. Design/methodology/approach: A computer-vision safety system is presented. Image segmentation, 3D point clouds, face recognition, hand gesture recognition, speed and trajectory tracking and a digital twin are used. Using speed and separation, the robot’s speed is controlled based on the nearest location of humans accurate to their body shape. The computer-vision safety system is compared to a traditional laser measure. The system is evaluated in a controlled test, and in the field. Findings: Computer-vision and lasers are shown to be equivalent by a measure of relationship and measure of agreement. R2 is given as 0.999983. The two methods are systematically producing similar results, as the bias is close to zero, at 0.060 mm. Using Bland–Altman analysis, 95% of the differences lie within the limits of maximum acceptable differences. Originality/value: In this paper an original model for future computer-vision safety systems is described which is equivalent to existing laser systems, identifies and adapts to particular humans and reduces the need to slow and stop systems thereby improving efficiency. The implication is that computer-vision can be used to substitute lasers and permit adaptive robotic control in human–robot collaboration systems.
AB - Purpose: Maintaining the safety of the human is a major concern in factories where humans co-exist with robots and other physical tools. Typically, the area around the robots is monitored using lasers. However, lasers cannot distinguish between human and non-human objects in the robot’s path. Stopping or slowing down the robot when non-human objects approach is unproductive. This research contribution addresses that inefficiency by showing how computer-vision techniques can be used instead of lasers which improve up-time of the robot. Design/methodology/approach: A computer-vision safety system is presented. Image segmentation, 3D point clouds, face recognition, hand gesture recognition, speed and trajectory tracking and a digital twin are used. Using speed and separation, the robot’s speed is controlled based on the nearest location of humans accurate to their body shape. The computer-vision safety system is compared to a traditional laser measure. The system is evaluated in a controlled test, and in the field. Findings: Computer-vision and lasers are shown to be equivalent by a measure of relationship and measure of agreement. R2 is given as 0.999983. The two methods are systematically producing similar results, as the bias is close to zero, at 0.060 mm. Using Bland–Altman analysis, 95% of the differences lie within the limits of maximum acceptable differences. Originality/value: In this paper an original model for future computer-vision safety systems is described which is equivalent to existing laser systems, identifies and adapts to particular humans and reduces the need to slow and stop systems thereby improving efficiency. The implication is that computer-vision can be used to substitute lasers and permit adaptive robotic control in human–robot collaboration systems.
KW - Adaptive
KW - Computer-vision
KW - Data fusion
KW - Human-robot collaboration
KW - Safety
KW - Speed and separation monitoring
UR - http://www.scopus.com/inward/record.url?scp=85200512078&partnerID=8YFLogxK
U2 - 10.1108/TECHS-12-2023-0054
DO - 10.1108/TECHS-12-2023-0054
M3 - Article
AN - SCOPUS:85200512078
SN - 2754-1312
VL - 3
SP - 309
EP - 331
JO - Technological Sustainability
JF - Technological Sustainability
IS - 3
ER -