Verifying Properties of an Electro-Mechanical Braking System

Abstract: In this experience report, we apply the hybrid verification tools iSAT-ODE, Flow*, and S-TaLiRo to a case study consisting of an experimental electro-mechanical braking system. Starting from a Simulink closed-loop model, we describe the derivation of hybrid automaton models for plant and controller and give verifcation results for the different tools.

“…These ranges are identified by model designers [9]. In general, the ranges for model inputs and configuration parameters should be identified by engineers who design and implement the models.…”

“…In the first experiment, we fix the BR(t) signal to the one used in [9] and vary the values of R and L within the ranges [0.4, 0.6] and [0.00025, 0.00175], respectively. These ranges are identified by model designers [9].…”

“…Our approach, however, is applicable not just to generic properties but also to controllers function-specific requirements. For example, the following requirement is specified for EMB [9]:…”

“…The above requirement (denoted by ϕ 1 ) can be formalized in terms of a temporal logic formula as follows [9]:…”

“…It is an experimental Electro-Mechanical Braking (EMB) system consisting of a physical (plant) model together with the software controller consisting of a discrete state machine (open-loop) and a continuous PID (closed-loop) controller. EMB is published by Bosch research lab as a representative benchmark model for cyber physical systems from the automotive domain [9] and is available at [8]. It is implemented in Matlab/Simulink [10].…”

Automated testing of hybrid Simulink/Stateflow controllers: industrial case studies

“…These ranges are identified by model designers [9]. In general, the ranges for model inputs and configuration parameters should be identified by engineers who design and implement the models.…”

“…In the first experiment, we fix the BR(t) signal to the one used in [9] and vary the values of R and L within the ranges [0.4, 0.6] and [0.00025, 0.00175], respectively. These ranges are identified by model designers [9].…”

“…Our approach, however, is applicable not just to generic properties but also to controllers function-specific requirements. For example, the following requirement is specified for EMB [9]:…”

“…The above requirement (denoted by ϕ 1 ) can be formalized in terms of a temporal logic formula as follows [9]:…”

“…It is an experimental Electro-Mechanical Braking (EMB) system consisting of a physical (plant) model together with the software controller consisting of a discrete state machine (open-loop) and a continuous PID (closed-loop) controller. EMB is published by Bosch research lab as a representative benchmark model for cyber physical systems from the automotive domain [9] and is available at [8]. It is implemented in Matlab/Simulink [10].…”

Automated testing of hybrid Simulink/Stateflow controllers: industrial case studies

Local Descent for Temporal Logic Falsification of Cyber-Physical Systems

PSY-TaLiRo: A Python Toolbox for Search-Based Test Generation for Cyber-Physical Systems