The present disclosure relates generally to methods and controls for internal combustion engines and, more particularly, to methods for controlling diesel engines. The methods and controls apply a Regularized and Smoothed Fischer Burmeister technique to model predictive control in order to control an engine in real time.
Modern diesel engines use variable geometry turbines (VGT) to increase the amount of air supplied to the engine cylinders. The VGT varies the angle of the turbine stator inlet vanes to change the amount of air supplied to the engine cylinders. In addition to providing optimum performance and fuel economy, modern diesel engines must also meet stringent federal regulations on emissions, particularly, particulate matter and nitrogen oxides. In order to meet all of these requirements, diesel engines with a VGT also use an exhaust gas recirculation (EGR) valve that has a variable controlled position to recirculate varying amounts of engine exhaust gases back into the engine cylinders to lower temperature of combustion, reduce NOx production and reduce engine emissions. As the engine operates over a large range of operating conditions, including engine speed, fuel usage, engine load, etc., one and typically multiple controllers are embedded in the engine control unit (ECU) to control various engine actuators in response to sensors detecting engine performance in order to optimize engine performance, and emissions.
An important example of a real-time, embedded optimization problem is model predictive control (MPC), where an optimal control problem over a receding horizon is solved during each sampling period. See L. Grüne and J. Pannek, “Nonlinear model predictive control,” in Nonlinear Model Predictive Control, pp. 43-66, Springer, 2011; J. B. Rawlings and D. Q. Mayne, Model predictive control: Theory and design. Nob Hill Pub., 2009; and G. C. Goodwin, M. M. Seron, and J. A. De Doná, Constrained control and estimation: an optimisation approach. Springer Science & Business Media, 2006, each incorporated herein by reference in their entirety. The optimal control problem for a discrete time linear-quadratic MPC formulation can be expressed as a convex QP. Furthermore, convex QPs form the basis for many algorithms used in nonlinear model predictive control (NMPC) such as sequential quadratic programming (SQP), or the real-time iteration scheme which solves just one QP per timestep. See P. T. Boggs and J. W. Tolle, “Sequential quadratic programming,” Acta numerica, vol. 4, pp. 1-51, 1995; S. Gros, M. Zanon, R. Quirynen, A. Bemporad, and M. Diehl, “From linear to nonlinear mpc: bridging the gap via the real-time iteration,” International Journal of Control, pp. 1-19, 2016; and M. Diehl, H. G. Bock, J. P. Schlöder, R. Findeisen, Z. Nagy, and F. Allgöwer, “Real-time optimization and nonlinear model predictive control of processes governed by differential-algebraic equations,” Journal of Process Control, vol. 12, no. 4, pp. 577-585, 2002, each incorporated herein by reference in their entirety.
The use of Model Predictive Control (MPC) is growing for engine control. For example, the rate-based MPC approach incorporates integral type action to guarantee zero steady state error by adding additional integral states to the predictive control model. The MPC model uses a number of different engine operating ranges (fuel rate and engine speed), and develops a controller for each range to control the engine actuators.
In a specific example of model predictive control applied to diesel engine airflow, the flows in the engine are controlled using the variable geometry turbine (TGT), EGR throttle, and an EGR valve actuator. These systems are strongly coupled and are highly non-linear.
However, existing methods for constrained optimal control in embedded automotive applications have been unable to perform required calculations within a time period necessary for real-time control. In a control system for a diesel engine, the Engine Control Unit (ECU) samples input signals, records measurements from sensors, performs calculations and issues commands. To accomplish real-time control, all of these operations must be performed within the sampling period. In particular, the ECU is given a fixed percentage of the sampling period to complete all required calculations, referred to as a computational budget.
In recent years a significant amount of research into developing fast, reliable algorithms for solving both QPs and more general optimization problems online has significantly advanced the state of the art. However, managing the computational burden of online optimization algorithms remains a challenge.
It would be desirable to provide a model predictive controller for use with internal combustion engine, which is fast enough to accomplish all required calculations within the computational budget.
The foregoing “Background” description is for the purpose of generally presenting the context of the disclosure. Work of the inventors, to the extent it is described in this background section, as well as aspects of the description which may not otherwise qualify as prior art at the time of filing, are neither expressly or impliedly admitted as prior art against the present invention.
A more complete appreciation of the disclosure and many of the attendant advantages thereof will be readily obtained as the same becomes better understood by reference to the following detailed description when considered in connection with the accompanying drawings, wherein:
Referring now to the drawings, wherein like reference numerals designate identical or corresponding parts throughout several views, the following description relates to techniques for constrained optimization applied to embedded model predictive control in a diesel engine.
Referring to
An Exhaust Gas Recirculation (EGR) valve 40 is coupled in a bypass path between the intake manifold 30 and the exhaust manifold 34 to recirculate a portion of the exhaust gases from the exhaust manifold 34 back into the intake manifold 32 for supply to the cylinders 24. An EGR cooler 42 may be coupled in the bypass path along with the EGR valve 40. An EGR throttle 44 is mounted in the airflow path from the compressor 46 of the variable geometry turbine (VGT) 48 to control gas circulation. An intercooler 50 may be mounted in the intake air path ahead of the EGR throttle 44. The variable geometry turbine 48, by controlling the angle of the turbine input vanes, controls the intake manifold pressure via the compressor 46.
The internal combustion engine 20 may be provided with sensors for pressure, temperature, air flow and engine speed. The sensors may include an intake manifold pressure (MAP) sensor, boost pressure sensor, a measured air flow (MAF) sensor, compressor flow sensor, and an engine speed reader. Provided readings from the sensors, other parameters may be estimated, which are referred to as estimators. Estimators may include burnt gas fractions for the intake and exhaust, torque, exhaust temperature, intake temperature, NOx, exhaust pressure, turbine speed, and air-fuel ratio.
Referring to
The eMPC 201 controls the EGR valve 40, EGR throttle 44 and variable geometry turbocharger 48. In doing so, the eMPC 201 is subject to emissions requirements (NOx, hydrocarbons, smoke), must supply a torque as requested by a driver, and is expected to conserve fuel (obtain good fuel economy).
It is desired to control drivability and fuel consumption of the internal combustion engine in real-time, using a system embedded in an Engine Control Unit (ECU), which typically is a small microcontroller. In particular, to be effective, the control operation performed by the eMPC controller 201, estimator 205 and airpath controller 203 should be performed during each sampling period in which sensor readings are made.
In an embodiment, the ECU may sample about 100× per second. During a sampling period, the ECU records measurements from sensors, performs optimization calculations, and issues commands. Thus, the ECU preferably performs its required operations within a fixed percentage of the sampling period, referred to as a computational budget.
Generally, a control operation may be considered as being solution of an optimization problem subject to constraints. One way to express an optimal control problem for a discrete time linear-quadratic MPC formulation is as a convex quadratic program (QP).
An aspect is a MPC, where the optimal control problem is solved during each sampling period.
An aspect is a MPC which applies the Fischer Burmeister (FB) function and Newton's method to solving convex QPs, and hereinafter is referred to as Fischer Burmeister Regularized Smoothed (FBRS) approach. FBRS has some properties which make it attractive for embedded optimization. (i) Firstly, FBRS displays global linear convergence and quadratic asymptotic convergence to the solution; properties it inherits from its nature as a damped generalized Newton's method. (ii) It is simple to implement. (iii) Finally, it can be effectively warmstarted when solving sequences of related QPs. In an example implementation, the control program is an embedded C program that is generated from MATLAB code.
As shown in
Regarding
In the mathematical representation, α, β, γ represent tuning gains, η represents engine efficiency (normalized power), s represents slack, R represents a damping matrix, u represents a set of stacked controls, and q represents a fueling rate. Further, x represents a differential state of the controller model, which may include a set of intake manifold pressure pim, exhaust pressure pex, compressor flow ωc, intake manifold burnt gas fraction F1, exhaust manifold burnt gas fraction F2, and filtered NOx θf. ρ represents an operating point for a target fuel rate and engine speed. ϕl and θl are limits on fuel air ratio and NOx, respectively.
Regarding
min(z)zTHz+fTz, subject to Az≤b,
where H∈Sn is the Hessian matrix, f∈n, z∈n, A∈q×n, b∈q. For simplicity the QP may be for the case where there are no equality constraints; one of ordinary skill would understand that the extension to equality and inequality constrained problems is straightforward. For this example, the Karush-Kuhn-Tucker (KKT) conditions for the QP are:
Hz+f+ATv=0
vTy=0
v≥0, y≥0
The variable z represents control actions, particularly those that minimize the cost function. The variable v represents sensitivities, which are internal variables calculated in the system that quantify how sensitive the cost function is to the constraints. The variable y=b−Az represents constraint margin. If y is positive, the constraints are satisfied. If y is negative, the constraints are not satisfied.
In order to solve the conditions for optimality using the FB function, S507, the conditions are rewritten as a function F(x) using the FB transform. For example, the complementarity conditions v≥0, y≥0, yTv=0 are replaced with FB equations ϕ(y,v), where x=(z, v) and y=b−Az. Applying the FB function to the complementarity conditions in yields the following nonlinear mapping,
Because of the properties of FB functions, the function F(x) has the property that F(x)=0 if and only if x satisfies the KKT conditions.
The FBRS algorithm functions by approximate solving a sequence of problems Fε
The mapping F(x) is single-valued but is not continuously differentiable; however, F(x) is semismooth so a semismooth Newton's method can be applied to the rootfinding problem F(x)=0. If F is smoothed (ε>0) then Fε(x) is continuously differentiable so (regular) Newton's method is applicable.
Regarding
xx+1=xk−tkVk−1Fε
where Vk∈∂CFε
where δ≥0 controls the regularization. The modified Newton iteration is then
xx+1=xk−tkKk−1Fε
where Kk=Vk+∇xR(xk,δ) is used in place of Vk.
The algorithm for FBRS is summarized in Algorithm 1, below, and represents a semismooth Newton's method globalized using a linesearch and homotopy. The merit function used to globalize each step of the algorithm is defined as
θ(x)ε=½∥Fε(x)∥22,
the parameter σ∈(0,0.5) encodes how much reduction is required in the merit function. The desired tolerance is denoted τ, and, β∈(0,1) controls reduction in the backtracking linesearch. More sophisticated algorithms for computing tk, e.g., polynomial interpolation can be used in place of the backtracking linesearch; however this simple algorithm is effective in practice. See C. T. Kelley, Iterative methods for optimization. SIAM, 1999, incorporated herein by reference in its entirety. Typical values for the fixed parameters are σ≈10−4 and β≈0.7.
A system which includes the features in the foregoing description provides numerous advantages. In particular, the eMPC described herein can optimize internal combustion engine performance in real-time, at each sensor sampling period.
Numerous modifications and variations are possible in light of the above teachings. It is therefore to be understood that within the scope of the appended claims, the invention may be practiced otherwise than as specifically described herein.
Thus, the foregoing discussion discloses and describes merely exemplary embodiments of the present invention. As will be understood by those skilled in the art, the present invention may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. Accordingly, the disclosure of the present invention is intended to be illustrative, but not limiting of the scope of the invention, as well as other claims. The disclosure, including any readily discernible variants of the teachings herein, defines, in part, the scope of the foregoing claim terminology such that no inventive subject matter is dedicated to the public.
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