Abstract
Modern scenarios in robotics involve human-robot collaboration or robot-robot cooperation in unstructured environments. In human-robot collaboration, the objective is to relieve humans from repetitive and wearing tasks. This is the case of a retail store, where the robot could help a clerk to refill a shelf or an elderly customer to pick an item from an uncomfortable location. In robot-robot cooperation, automated logistics scenarios, such as warehouses, distribution centers and supermarkets, often require repetitive and sequential pick and place tasks that can be executed more efficiently by exchanging objects between robots, provided that they are endowed with object handover ability. Use of a robot for passing objects is justified only if the handover operation is sufficiently intuitive for the involved humans, fluid and natural, with a speed comparable to that typical of a human-human object exchange. The approach proposed in this paper strongly relies on visual and haptic perception combined with suitable algorithms for controlling both robot motion, to allow the robot to adapt to human behavior, and grip force, to ensure a safe handover. The control strategy combines model-based reactive control methods with an event-driven state machine encoding a human-inspired behavior during a handover task, which involves both linear and torsional loads, without requiring explicit learning from human demonstration. Experiments in a supermarket-like environment with humans and robots communicating only through haptic cues demonstrate the relevance of force/tactile feedback in accomplishing handover operations in a collaborative task.
Highlights
Recent studies testify an increasing use of robots in retail environments with a number of objectives: to relieve staff from repetitive tasks with low added value; to reallocate clerks to customer-facing activities; to gather in-store data for real-time inventory to reduce out-ofstock losses (Retail Analytics Council, 2020)
The controller is based on the ViSP library (Marchand et al, 2005) and uses the images acquired from an RGB-D camera (RealSense D435i in Figure 1) to adjust the robot pose with respect to the object and correctly grasp it
According to the feedback given by different subjects during several trials, we decided to switch off the slipping avoidance (SA) dynamic control action because the subjects complained for an annoying vibration felt during the load sharing caused by the controller reaction to the slight trembling of the receiver
Summary
Recent studies testify an increasing use of robots in retail environments with a number of objectives: to relieve staff from repetitive tasks with low added value; to reallocate clerks to customer-facing activities; to gather in-store data for real-time inventory to reduce out-ofstock losses (Retail Analytics Council, 2020). Even parallel grippers are able to perform in-hand manipulation actions as demonstrated by Costanzo et al (2020a) Both object and gripper pivoting maneuvers are used in this paper to achieve this objective, for instance, choosing an object orientation so as to avoid high torsional loads at receiver fingertips in case a precision grasp is needed to take the object. This can likely happen in a collaborative packaging task where the human operator has to arrange in a box the items passed by the robot.
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