Abstract
Safety critical events in robotic applications can often be characterized by forces between the robot end-effector and the environment. One application in which safe interaction between the robot and environment is critical is in the area of medical robots. In this paper, we propose a novel Compact Form Dynamic Linearization Model-Free Prediction (CFDL-MFP) technique to predict future values of any time-series sensor data, such as interaction forces. Existing time series forecasting methods have high computational times which motivates the development of a novel technique. Using Autoregressive Integrated Moving Average (ARIMA) forecasting as benchmark, the performance of the proposed model was evaluated in terms of accuracy, computation efficiency, and stability on various force profiles. The proposed algorithm was 11% more accurate than ARIMA and maximum computation time of CFDL-MFP was 4ms, compared to ARIMA (7390ms). Furthermore, we evaluate the model in the special case of predicting needle buckling events, before they occur, by using only axial force and needle-tip position data. The model was evaluated experimentally for robustness with steerable needle insertions into different tissues including gelatin and biological tissue. For a needle insertion velocity of 2.5mm/s, the proposed algorithm was able to predict needle buckling 2.03s sooner than human detections. In biological tissue, no false positive or false negative buckling detections occurred and the rates were low in artificial tissue. The proposed forecasting model can be used to ensure safe robot interactions with delicate environments by predicting adverse force-based events before they occur.
Highlights
The technique of predicting future events based on past and present information of a system has played a significant role in framing optimal and safe decisions for various applications such as mobile surveillance, high-performance manipulation and medical applications to name a few [1]
The insertion path was greater than 11cm for lower duty-cycles due to which a force increase was alerted at 12.41cm for DC = 0% insertion and a buckling was predicted 0.1cm (0.4s for ν = 2.5mm/s) ahead before detection
Force forecasting for early prediction of critical events in robotics was low since the points of force increase alert were at the intersection of the rapidly changing forces, similar to profiles (E,F) from Section 4.2.1
Summary
The technique of predicting future events based on past and present information of a system has played a significant role in framing optimal and safe decisions for various applications such as mobile surveillance, high-performance manipulation and medical applications to name a few [1]. Accuracy and timely predictions of a system state in response to environmental conditions enhance the ability to provide appropriate control decisions for safe system operations. Given the unknown dynamic structure of environments, it is challenging to control the system’s response to its environment. Force forecasting for early prediction of critical events in robotics
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