This example shows how to combine Stateflow® with Simulink® to efficiently model hybrid systems. This type of modeling is particularly useful for systems that have numerous possible operational modes based on discrete events. Traditional signal flow is handled in Simulink while changes in control configuration are implemented in Stateflow. The model described below represents a fuel control system for a gasoline engine. The system is highly robust in that individual sensor failures are detected and the control system is dynamically reconfigured for uninterrupted operation.
Physical and empirical relationships form the basis for the throttle and intake manifold dynamics of this model. The air-fuel ratio is computed by dividing the air mass flow rate (pumped from the intake manifold) by the fuel mass flow rate (injected at the valves). The ideal (i.e. stoichiometric) mixture ratio provides a good compromise between power, fuel economy, and emissions. The target air-fuel ratio for this system is 14.6. Typically, a sensor determines the amount of residual oxygen present in the exhaust gas (EGO). This gives a good indication of the mixture ratio and provides a feedback measurement for closed-loop control. If the sensor indicates a high oxygen level, the control law increases the fuel rate. When the sensor detects a fuel-rich mixture, corresponding to a very low level of residual oxygen, the controller decreases the fuel rate.
Figure 1 shows the top level of the Simulink model. To open the model, type
sldemo_fuelsys in MATLAB® Command Window. Press the Play button in the model window toolbar to run the simulation. The model loads necessary data into the model workspace from
sldemo_fuelsys_data.m. The model logs relevant data to MATLAB workspace in a data structure called
sldemo_fuelsys_output. Logged signals have a blue indicator (see Figure 1).
Note that loading initial conditions into the model workspace keeps simulation data isolated from data in other open models that you may have open. This also helps avoid MATLAB workspace cluttering. To view the contents of the model workspace select View > Model Explorer > Model Explorer, and click on Model Workspace from the Model Hierarchy list.
Notice that units are visible on the model and subsystem icons and signal lines. Units are specified on the ports and on the bus object. To learn more about units in Simulink see Simulink Units.
Figure 1: Top-level diagram for the fuel control system model
The fuel_rate_control uses signals from the system's sensors to determine the fuel rate which gives a stoichiometric mixture. The fuel rate combines with the actual air flow in the engine gas dynamics model to determine the resulting mixture ratio as sensed at the exhaust.
The user can selectively disable each of the four sensors (throttle angle, speed, EGO and manifold absolute pressure [MAP]), to simulate failures. Simulink accomplishes this with Manual Switch blocks. Double-click on the block to change the position of the switch. Similarly, the user can induce the failure condition of a high engine speed by toggling the switch on the far left. A Repeating Table block provides the throttle angle input and periodically repeats the sequence of data specified in the mask.
The fuel_rate_control block, shown in Figure 2, uses the sensor input and feedback signals to adjust the fuel rate to give a stoichiometric ratio. The model uses three subsystems to implement this strategy: control logic, airflow calculation, and fuel calculation. Under normal operation, the model estimates the airflow rate and multiplies the estimate by the reciprocal of the desired ratio to give the fuel rate. Feedback from the oxygen sensor provides a closed-loop adjustment of the rate estimation in order to maintain the ideal mixture ratio.
Figure 2: Fuel rate controller subsystem
A single Stateflow chart, consisting of a set of six parallel states, implements the control logic in its entirety. The four parallel states shown at the top of Figure 3 correspond to the four individual sensors. The remaining two parallel states at the bottom consider the status of the four sensors simultaneously and determine the overall system operating mode. The model synchronously calls the entire Stateflow diagram at a regular sample time interval of 0.01 sec. This permits the conditions for transitions to the correct mode to be tested on a timely basis.
To open the control_logic Stateflow chart, double click on it in the fuel_rate_control subsystem.
Figure 3: The control logic chart
When execution begins, all of the states start in their
normal mode with the exception of the oxygen sensor (EGO). The
O2_warmup state is entered initially until the warmup period is complete. The system detects throttle and pressure sensor failures when their measured values fall outside their nominal ranges. A manifold vacuum in the absence of a speed signal indicates a speed sensor failure. The oxygen sensor also has a nominal range for failure conditions but, because zero is both the minimum signal level and the bottom of the range, failure can be detected only when it exceeds the upper limit.
Regardless of which sensor fails, the model always generates the directed event broadcast
Fail.INC. In this way the triggering of the universal sensor failure logic is independent of the sensor. The model also uses a corresponding sensor recovery event,
Fail state keeps track of the number of failed sensors. The counter increments on each
Fail.INC event and decrements on each Fail.DEC event. The model uses a superstate,
Multi, to group all cases where more than one sensor has failed.
The bottom parallel state represents the fueling mode of the engine. If a single sensor fails, operation continues but the air/fuel mixture is richer to allow smoother running at the cost of higher emissions. If more than one sensor has failed, the engine shuts down as a safety measure, since the air/fuel ratio cannot be controlled reliably.
During the oxygen sensor warm-up, the model maintains the mixture at normal levels. If this is unsatisfactory, the user can change the design by moving the warm-up state to within the
Rich_Mixture superstate. If a sensor failure occurs during the warm-up period, the
Single_Failure state is entered after the warm-up time elapses. Otherwise, the
Normal state is activated at this time.
A protective overspeed feature has been added to the model by creating a new state in the
Fuel_Disabled superstate. Through the use of history junctions, we assured that the chart returns to the appropriate state when the model exits the overspeed state. As the safety requirements for the engine become better specified, we can add additional shutdown states to the
When a sensor fails, an estimate of the sensor is computed. For example, open the pressure sensor calculation. Under normal sensor operation the value of the pressure sensor is used. Otherwise, the value is estimated.
ans = 0
The estimate of manifold pressure is computed as a function of engine speed and throttle position. The value is computed conveniently using a Simulink function inside Stateflow.
The Airflow Calculation block (shown in Figure 5) is the location for the central control laws. This block is found inside the fuel_rate_control subsystem (open this block). The block estimates the intake air flow to determine the fuel rate which gives the appropriate air/fuel ratio. Closed-loop control adjusts the estimation according to the residual oxygen feedback in order to maintain the mixture ratio precisely. Even when a sensor failure mandates open-loop operation, the most recent closed-loop adjustment is retained to best meet the control objectives.
Figure 5: Airflow estimation and correction
The engine's intake air flow can be formulated as the product of the engine speed, the manifold pressure and a time-varying scale factor.
Cpump is computed by a lookup table and multiplied by the speed and pressure to form the initial flow estimate. During transients, the throttle rate, with the derivative approximated by a high-pass filter, corrects the air flow for filling dynamics. The control algorithm provides additional correction according to Equation 2.
Figure 6: Engine Gas Dynamics subsystem
Figure 7: Mixing & Combustion block within the Engine Gas Dynamics subsystem
The nonlinear oxygen sensor (EGO Sensor block) is found inside the Mixing & Combustion block (see Figure 7) within the Engine Gas Dynamics subsystem (see Figure 6). EGO Sensor is modeled as a hyperbolic tangent function, and it provides a meaningful signal when in the vicinity of 0.5 volt. The raw error in the feedback loop is thus detected with a switching threshold, as indicated in Equation 2. If the air-fuel ratio is low (the mixture is lean), the original air estimate is too small and needs to be increased. Conversely, when the oxygen sensor output is high, the air estimate is too large and needs to be decreased. Integral control is utilized so that the correction term achieves a level that brings about zero steady-state error in the mixture ratio.
The normal closed-loop operation mode, LOW, adjusts the integrator dynamically to minimize the error. The integration is performed in discrete time, with updates every 10 milliseconds. When operating open-loop however, in the RICH or O2 failure modes, the feedback error is ignored and the integrator is held. This gives the best correction based on the most recent valid feedback.
The fuel_calc subsystem (within the fuel_rate_control subsystem, see Figure 8) sets the injector signal to match the given airflow calculation and fault status. The first input is the computed airflow estimation. This is multiplied with the target fuel/air ratio to get the commanded fuel rate. Normally the target is stoichiometric, i.e. equals the optimal air to fuel ratio of 14.6. When a sensor fault occurs, the Stateflow control logic sets the mode input to a value of 2 or 3 (RICH or DISABLED) so that the mixture is either slightly rich of stoichiometric or is shut down completely.
Figure 8: fuel_calc subsystem
The fuel_calc subsystem (Figure 8) employs adjustable compensation (Figure 9) in order to achieve different purposes in different modes. In normal operation, phase lead compensation of the feedback correction signal adds to the closed-loop stability margin. In RICH mode and during EGO sensor failure (open loop), however, the composite fuel signal is low-pass filtered to attenuate noise introduced in the estimation process. The end result is a signal representing the fuel flow rate which, in an actual system, would be translated to injector pulse times.
Figure 9: Switchable compensation subsystem
Simulation results are shown in Figure 10 and Figure 11. The simulation is run with a throttle input that ramps from 10 to 20 degrees over a period of two seconds, then goes back to 10 degrees over the next two seconds. This cycle repeats continuously while the engine is held at a constant speed so that the user can experiment with different fault conditions and failure modes. Double-click on a sensor switch in the model to simulate the failure of the associated sensor. Repeat this operation to toggle the switch back for normal operation.
Figure 10: Comparing the fuel flow rate for different sensor failures
Figure 10 compares the fuel flow rate under fault-free conditions (baseline) with the rate applied in the presence of a single failure in each sensor individually. In each case note the nonlinear relationship between fuel flow and the triangular throttle command (shown in Figure 12). In the baseline case, the fuel rate is regulated tightly, exhibiting a small ripple due to the switching nature of the EGO sensor's input circuitry. In the other four cases the system operates open loop. The control strategy is proven effective in maintaining the correct fuel profile in the single-failure mode. In each of the fault conditions, the fuel rate is essentially 125% of the baseline flow, fulfilling the design objective of 80% rich.
Figure 11: Comparing the air-fuel ratio for different sensor failures
Figure 11 plots the corresponding air/fuel ratio for each case. The baseline plot shows the effects of closed-loop operation. The mixture ratio is regulated very tightly to the stoichiometric objective of 14.6. The rich mixture ratio is shown in the bottom four plots of Figure 11. Although they are not tightly regulated, as in the closed-loop case, they approximate the objective of air/fuel (0.8*14.6=11.7).
Figure 12: Throttle command
The transient behavior of the system is shown in Figure 13. With a constant 12 degree throttle angle and the system in steady-state, a throttle failure is introduced at t = 2 and corrected at t = 5. At the onset of the failure, the fuel rate increases immediately. The effects are seen at the exhaust as the rich ratio propagates through the system. The steady-state condition is then quickly recovered when closed-loop operation is restored.
Figure 13: Transient response to fault detection
With animation enabled in the Stateflow debugger, the state transitions are highlighted in the Stateflow diagram (see Figure 3) as the various states are activated. The sequence of activation is indicated by changing colors. This closely coupled synergy between Stateflow and Simulink fosters the modeling and development of complete control systems. An engineer's concepts can develop in a natural and structured fashion with immediate visual feedback reinforcing each step.
Refer to other examples related to sldemo_fuelsys:
Fixed-point design: fxpdemo_fuelsys
Production C/C++ code generation: Air-Fuel Ratio Control System with Stateflow Charts
Fixed-point production C/C++ code generation: Air-Fuel Ratio Control System with Fixed-Point Data