**1. Introduction**

X-By-Wire technologies are the future of the automotive industry due to an increasing demand for electrification and fuel efficiency. Their electronic architectures and interface also make them a great candidate for autonomous and hybrid electric/electric vehicles. Among all the necessary by-wire technologies, brake-bywire systems are a priority due to their safety-critical nature role in the vehicle [1, 2].

Brake-by-wire systems can reduce component weight and allow the actuators to consume energy only when required by blending both regenerative braking and friction braking. This can minimize fuel consumption and CO2 emissions. Using sensors and control methods, caliper drag can be eliminated by making brake-bywire technology even more energy efficient. Individual wheel braking and faster activation time can be combined with the vehicle's ECS system to make the vehicle safer. The reliability of new actuators and the risk and cost associated with deploying new brake technologies are the main hurdles of brake-by-wire systems becoming a popular choice for the automotive manufacturers [3, 4].

Brake systems are categorized into wet and dry brakes. Wet brakes employ fluids for their operation, and dry brakes are usually purely mechanical systems. Electro-hydraulic brake systems are a type of wet brakes where their pressure is modified using pressure modulators that can be controlled electronically. The pressure source can be packaged in one centralized location for all four wheels like Bosch's first electro-hydraulic brake system [5], or it can be local to each wheel like MKC-l from Continental [6] (local Electro-hydraulic brakes). Dry brakes can also be realized in a few different configurations. There is an electro-mechanical brake that utilizes a small motor, planetary gear set and a roller-screw to move the brake pad [7–13]. However, this type of brake requires a 42 Volt motor to operate and consumes a lot of energy [3]. Electronic-wedge brakes on the other hand, uses a wedge mechanism to create a system that draws the wedge pad inside the brake; therefore, requiring less energy to operate [13–21]. Vienna Engineering also came up with a similar idea that uses a crank-shaft mechanism that reduces the complexity of reduction gears and roller screws [22–25].

Purely dry brakes such as Electronic Wedge and VE brakes, are going to be costlier that Electro-Hydraulic brakes since they are newer technologies and require more research and development to productionize. On the other hand, EHB has already been in the market for a while. The other challenge for purly dry brakes is reliability since they have more electronic components and they all need to reliably perform in a harsh environment near the brake where vibration, shock and high temperatures can have significant impact [3].

In this work, we have chosen to study Electro-Hydraulic (EHB), Electro-Mechanical (EMB) and Electronic Wedge Brakes (EWB). We will start by modeling the brakes using bond graph in Section 2. Bond graph is graphical representation method to model dynamical systems that utilizes flow of energy. It is an easy and intuitive way to model physical systems especially the ones that are in the multienergy domain (e.g. Electro-Mechanical, Electro-Hydraulic). Readers can take a look at [26] for further readings on bond graphs.

After modeling the actuators, we will design the controllers using Youla Paramerization technique. Finally, we will add disturbance rejection and compare results for EMB and EWB controllers and show their effectiveness. The purpose of this book chapter is to show the process of modeling of three different brake-bywire actuators and designing their robust controllers using Youla paramerization.

#### **2. System modeling**

In this section, we discuss the schematics, bond graphs, and the equations of motion based on the bond graphs for each brake system. All the actuator models include a one-wheel vehicle model that is represented in **Figure 1**. It includes a moving wheel with a rotational inertia connected to a point mass. This simple dynamic model is very useful for preliminary studies of brake actuators and algorithms (such as ABS and TCS) and is easy to implement on the test rig. This simple

**Figure 1.** *One-wheel vehicle model used to analyze the brake actuator behaviors.*

*New Robust Control Design of Brake-by-Wire Actuators DOI: http://dx.doi.org/10.5772/intechopen.94581*

model is only utilized to study longitudinal dynamic effects in the vehicle. This model suffices for studying most of the brake-by-wire actuators and ABS technologies since it focuses on the longitudinal dynamics of the vehicle. Higher fidelity vehicle models, which include lateral dynamics, such as bicycle model and extended bicycle model will be considered in the future, once the preliminary comparisons of different actuators are studied and revealed using this simple model [25, 27–30]. The bond graph of this model is included in **Figure 2**.

State equations for this model are as follows

$$
\dot{p}\_{\dot{\alpha}} = f\_w \dot{\alpha} = F\_b R\_{\xi \overline{f}} - \tau\_b - Bo \tag{1}
$$

$$
\dot{p}\_u = m\dot{u} = -F\_b \tag{2}
$$

Where u is forward velocity, *ω* is wheel angular velocity, *τ<sup>b</sup>* is braking torque, *Fb* is braking force, N is normal force, B is bearing friction coefficient, *Reff* is effective wheel radius, *p<sup>ω</sup>* is the angular momentum of the wheel, and *pu* is the vehicle's momentum. For the braking force modeling, the Burckhardt tire model is chosen in which the coefficient of friction ð Þ *μ* is a function of the longitudinal slip ð Þ*λ* (Eq. 4) and the longitudinal slip is defined in Eq. 3 [31, 32].

$$
\lambda = \frac{u - a\mathbb{R}\_{\mathcal{G}}}{|u|} \tag{3}
$$

$$F\_b = \mu(\lambda) \cdot N = \left[c\_1(\mathbf{1} - e^{-c\_2\lambda}) - c\_3\lambda\right] \cdot N \tag{4}$$

where *N* is the normal force. The state equations describing the one-wheel model will always be present in all brake type models since the vehicle model will stay the same.

#### **2.1 Electro-hydraulic brake actuator**

The schematic of an electro-hydraulic brake (EHB) actuator is presented in **Figure 3**. It includes a hydraulic pipe which carries the hydraulic fluid with the pressure input ð Þ *Pin* to a cylinder chamber, which in turn changes this pressure into the movement of the brake pad. Therefore, the brake pad movement results in stopping the brake disk from moving [33].

The bond graph model is derived based on the schematic in **Figure 3**. The input is modulated pressure, and this pressure is an input to the hydraulic line, where, by using a transformer, it results in the brake pad movement (the pressure reservoir and the motor that modulates the pressure are not included in the model and will be added in the future studies). The interaction between the brake pad and the wheel is modeled with a stiffness ð Þ *kcal* . Brake torque is also modeled by a modulated resistance which changes with the displacement of the brake pad.

State equations (Eq. 5–8) are derived based on the bond graph in **Figure 4**.

**Figure 2.** *One-wheel bond graph.*

**Figure 3.** *Electro-hydraulic brake actuator EHB* ð Þ *schematics [33].*

**Figure 4.** *EHB bond graph.*

*New Robust Control Design of Brake-by-Wire Actuators DOI: http://dx.doi.org/10.5772/intechopen.94581*

$$
\dot{p}\_{line} = P\_{in} - R\_{line} \frac{p\_{line}}{I\_{line}} - q\_w \frac{\beta\_b f}{V\_{0\_w}} \tag{5}
$$

$$
\dot{q}\_w = \frac{p\_{\text{line}}}{I\_{\text{line}}} - A\_w \frac{p\_w}{m\_w} \tag{6}
$$

$$
\dot{p}\_w = A\_w q\_w \frac{\beta\_{hf}}{V\_{0\_w}} - b\_w \frac{p\_w}{m\_w} - q\_{cal} k\_{cal} \tag{7}
$$

$$
\dot{q}\_{cal} = \frac{p\_w}{m\_w} \tag{8}
$$

Where *Rline*, *pline*,*Iline*, *βhf* ,*V*0*<sup>w</sup>* , *Aw*, *pw*,*Vw*, and *qcal* are hydraulic line resistance, hydraulic line pressure, line inertia, bulk modulus, volume of cylinder chamber, surface area of the piston, pressure on the brake pad, velocity of the brake pad, and brake pad position, respectively. The brake torque is calculated using Eq. 9.

$$\pi\_b = \begin{cases} 2\mu\_{cal} r\_{\rm eff} k\_{cal} (\varkappa\_{cal} - \varkappa\_0) \quad , & \text{if } \varkappa\_{cal} \ge \varkappa\_0 \\ 0, & \text{otherwise} \end{cases} \tag{9}$$

Where *μcal*,*reff* , *xcal*, and *x*<sup>0</sup> are brake friction coefficient between the pad and the wheel, brake pad effective radius, brake pad position (same as *qcal*), and brake clearance, respectively. Eqs. 5–9 along with Eqs. 1–4 present the state equations for this brake system [29].

#### **2.2 Electro-mechanical brake actuator**

**Figure 5** shows a schematic of an electro-mechanical brake actuator. It consists of an electric motor, planetary gear set, ball screw, piston, brake pad, and floating caliper to oppose the brake pad. In this actuator, the motor's rotational motion becomes the brake pad's movement through one (or more) planetary gear sets and a ball screw mechanism. This movement will then create a clamp force given by *Fcl* in **Figure 5** [10, 34].

**Figure 6** illustrates the bond graph model for an electro-mechanical brake actuator (EMB). The input to the system is voltage ð Þ *Vin* to the motor. The motor includes an inductance ð Þ *Lm* and a resistance ð Þ *Rm* . The motor's current is proportional to a torque on the shaft and this proportionality is modeled by a gyrator (with *Kt* representing the motor constant). The shaft has a rotational inertia ð Þ *Jm* . The resistance that exists inside the planetary gear set, the ball-screw mechanism and the motor shaft is lumped together and modeled by an R-element. This resistance element is explained more in the next section.

**Figure 5.** *EMB Schematics (adapted from [34, 35]).*

The transformer is then used for the planetary gear set ratio *Npl* � � and the ballscrew mechanism lead ratio ð Þ *NScrew* . And finally, the interaction between the brake pad and the wheel is modeled with a stiffness similar to the one in the electrohydraulic brake system's bond graph ð Þ *Kcal* .

Based on the bond graph in **Figure 6**, the state equations are presented in Eqs. 10–12. Also, the brake torque is calculated similar to the EHB actuator using Eq. 9.

$$\dot{I}\_m = \frac{1}{L\_m} \left( V\_{in} - R\_m \cdot I\_m - K\_t \cdot o\_m \right) \tag{10}$$

$$\dot{\alpha}\_{m} = \frac{1}{J\_{m}} \left( K\_{t} \cdot I\_{m} - D\_{m} \cdot \alpha\_{m} - \tau\_{f} - N\_{p} \cdot N\_{s} \cdot K\_{cal} \cdot \max \left( \mathbf{x}\_{cal} - \mathbf{x}\_{0}, \mathbf{0} \right) \right) \tag{11}$$

$$
\dot{\mathbf{X}}\_{cal} = \mathbf{N}\_s \cdot \mathbf{N}\_p \cdot o\_m \tag{12}
$$

The lumped friction torque *τ <sup>f</sup>* � � is modeled using Karnopp friction with the Coulomb friction torque ð Þ *τ<sup>c</sup>* and maximum stiction torque ð Þ *τ<sup>s</sup>* having an affine relationship with the clamp force ð Þ *Fcl* . The area around zero of the motor rotational velocity is given by *dω*, and *ω<sup>m</sup>* is the motor's rotational velocity and *τpl*<sup>0</sup> is the friction torque when the shaft is not moving. C and G are constants that can be acquired using experimental results [10, 36].

$$\tau\_f = \begin{cases} \tau\_c \cdot \text{sign}(o\_m) + b\_v \cdot o\_m & |o\_m| \ge \text{d}\alpha \\ \min\left( |\tau\_{pl\_0}|, |\tau\_s|| \right) \cdot \text{sign}\left(\tau\_{pl\_0}\right) & \text{else} \\ \ast & C \cdot C \cdot E \end{cases} \tag{13}$$

$$
\boldsymbol{\tau}\_{\boldsymbol{c}} = \mathbf{C} + \mathbf{G} \cdot \mathbf{F}\_{\boldsymbol{d}} \tag{14}
$$

#### **2.3 Electronic wedge brake actuator**

We can draw the schematic for the wedge and the caliper in **Figure 7**. The motor's rotational velocity is being translated through a planetary gear set (not shown in the schematic) and a roller screw to a linear force on the wedge. Motor *New Robust Control Design of Brake-by-Wire Actuators DOI: http://dx.doi.org/10.5772/intechopen.94581*

**Figure 7.** *EWB schematics.*

shaft's axial stiffness and resistance is also added to the system. *Kcaliper* represents the stiffness of the caliper itself the stiffness between the wedge and the disk.

If we write the force equations for the wedge brake, we can get X-direction:

$$m\_w \dot{V}\_w = F\_M \cos \beta + F\_B - F\_R \sin a \tag{15}$$

Y-direction:

$$m\_w \dot{V}\_w \tan\left(a\right) = F\_M \sin\beta - F\_N + F\_R \cos a \tag{16}$$

And for the disk surface, we can write

$$F\_N = K\_{\text{Ca1}} \cdot X\_w \tan\left(a\right) \tag{17}$$

By rearranging Eqs. 15–17, we can remove the reaction force in the equations and write Eq. 18. We have incorporated Eq. 18 into the bond graph using 3 transformers.

$$\dot{V}\_W = \frac{1}{m\_W(1 + \tan^2 a)} \left(\frac{1}{\cos a} F\_M + (\mu\_{cal} - \tan a) \tan a (K\_{cal}) \cdot X\_w\right) \tag{18}$$

**Figure 8** represents the bond graph of the electronic wedge brake. The input to the system is motor voltage. The electric motor section remains the same as discussed in the previous sections. The transformer includes the roller-screw's lead ratio *<sup>L</sup>* 2*π* and the planetary gear set's gear ratio (N). For the sake of simplicity, we assume, *α* ¼ *β: FB* is the brake force that can be calculated from the relative velocity between the caliper and the wheel; however, since the wheel's velocity is much faster than the caliper's velocity, for the sake of simplicity, we assume that it would only be a function of caliper's movement. Finally, the transformer gains Tl, T2, and T3, based on Eq. 18, will become Eqs. 19–21.

$$T\_1 = \frac{1}{\cos a} \cdot \frac{1}{1 + \tan^2 a} = \cos(a) \tag{19}$$

**Figure 8.** *EWB's Bond Graph.*

$$T\_2 = \frac{1}{1 + \tan^2 a} \tag{20}$$

$$T\_3 = \frac{\tan a}{1 + \tan^2 a} \tag{21}$$

Based on the bond graph, the equations of motion for the wedge brake are provided by Eqs. 22–28. Brake Torque is also calculated the same as other actuators.

$$\dot{i}\_m = \frac{1}{L\_m} (V\_{in} - i\_m \cdot R\_m - K\_m \cdot o\_m) \tag{22}$$

$$
\dot{q}\_{\text{ax}} = LN a \nu - \frac{V\_w}{\cos\left(a\right)}\tag{23}
$$

$$F\_m = K\_{ax}q\_{ax} + D\_{ax}\dot{q}\_{ax} \tag{24}$$

$$
\dot{\boldsymbol{\omega}} = \frac{1}{J\_m} \{ \mathbf{K}\_m \dot{\mathbf{i}}\_m - \mathbf{D}\_m \cdot \boldsymbol{\alpha} - \mathbf{L} \cdot \mathbf{N} \cdot \mathbf{F}\_m \} \tag{25}
$$

$$\dot{W}\_w = \frac{1}{M\_w(1 + \tan^2(a))} \{ \frac{F\_m}{\cos(a)} + (K\_{cal} \cdot X\_w \cdot \tan\left(a\right)(\mu\_{cal} - \tan\left(a\right)) \}\tag{26}$$

$$
\dot{X}\_w = V\_w \tag{27}
$$

$$F\_b = \mu\_{cal} K\_{cal} X\_w \tan\left(a\right) \tag{28}$$

#### **3. Control strategy**

In this section, we discuss the control strategy for each brake actuator. For each of the brake actuators, a transfer function is obtained using the linearized equations of motion provided in the previous sections (all the nonlinearities in the frictions and caliper stiffness are linearized). Controllers in each case are designed using Youla-Kucera parameterization, which we will discuss in details in this section. This *New Robust Control Design of Brake-by-Wire Actuators DOI: http://dx.doi.org/10.5772/intechopen.94581*

control strategy ensures internal stability, robustness, and reference tracking of the closed-loop system.

In the electro-hydraulic brake actuator, the pressure is the input and the output is brake force *Gp* <sup>¼</sup> *Fb Pin* . A controller was designed around the plant to follow a specific brake reference force. In practice, we would need to either estimate the brake force (or brake torque) or use a sensor to acquire that information [29]. For the electro-mechanical and electronic-wedge brakes, a cascaded control scheme is used. The schematics of these control architectures are shown in **Figures 9** and **10** [8, 10]. In the cascaded control scheme, each inner closed-loop system is a new plant for the outer loop controller design. In this case, for the first loop, the input is the motor's voltage and the output is the motor's current. For the second loop, the input is the motor's current and the output is the motor's angular velocity. Lastly, for the most outer loop, the input is the motor's angular velocity and the output is clamping force (the normal force that clamps the wheel). Cascaded control increase performance and robustness of systems with relatively more nonlinearities. Hence, the controllers for the EMB and EWB were designed using cascaded control since they have more nonlinearities (e.g. mechanical friction) than the standard EHB. The current and angular velocity of the shaft can be directly measured while the clamp force requires to either be estimated or measured using a force sensor. Additionally, each loop has a disturbance which we will ignore in the first part of the control design. Later, we will use a disturbance rejection scheme to migitage the effect of these disturbances.

#### **3.1 Robust control design using Youla parameterization**

Youla parameterization is a robust control technique that allows for shaping the desired closed-loop transfer function (T), known as complimentary sensitivity transfer function, while ensuring internal stability, disturbance rejection at low frequency, and sensor noise and unmodeled disturbance rejections at high frequencies. The main

**Figure 9.** *Overall control architecture of EHB actuator.*

**Figure 10.** *Overall control architecture of EMB and EWB actuators.*

idea is to shape the closed-loop transfer function (T) with a transfer function called Youla Y s ð Þ ð Þ , which when multiplied by the plant transfer function *Gp* would become the closed loop transfer function (Eq. 29). To have a good tracking performance at steady-state, T sð Þshould be one in magnitude at low frequencies, it should be small in magnitude at high frequencies to ensure high frequency disturbance rejection.

$$T(\mathfrak{s}) = \mathbf{G}\_p(\mathfrak{s}) \cdot Y(\mathfrak{s}) \tag{29}$$

Therefore, according to Eq. 29, we can shape the closed-loop transfer function (provided that we meet the interpolation conditions, for ensuring internal stability, mentioned below). It is worth noting that Youla transfer function is related to the actuator effort so having a low magnitude Youla especially at high frequencies would keep the actuator effort low.

The closed loop transfer function T s ð Þ ð Þ is complementary to the sensitivity transfer function S s ð Þ ð Þ and the vector sum of these two transfer functions as given by (Eq. 30) is known as algebraic constraint. Therefore, this sensitivity transfer function should be small at low frequencies (to reject low frequency disturbances) and equal to one in magnitude at high frequencies due to the algebraic constraint.

$$S(\mathfrak{s}) = \mathfrak{1} - T(\mathfrak{s}) \tag{30}$$

If *Gp* is stable, the feedback loop would be internally stable if and only if Y sð Þ is selected to be stable. When *Gp* is not stable, *Y s*ð Þ, *S s*ð Þ, *T s*ð Þ, and *GpS* must all be stable to make the feedback loop internally stable. Therefore, to meet these conditions if there is an unstable pole *α<sup>p</sup>* repeated n times in the plant *Gp* , Eqs. 31 and 32, which are the interpolation conditions, have to be met (If the unstable pole is not repeated, Eq. 31 would suffice to meet the interpolation conditions).

$$T(a\_p) = \mathbf{1}, \ \mathbb{S}(a\_p) = \mathbf{0} \tag{31}$$

$$\frac{d^k T}{ds^k}(a\_p) = 0, \ \frac{d^k S}{ds^k}(a\_p) = 0, \ \quad \text{For} \quad \mathbf{1} \le k \le n \tag{32}$$

For a non-minimum phase zero ð Þ *α<sup>z</sup>* repeated n time, zeros in the RHP (Right Half Plane), the interpolation conditions are given by Eqs. 33 and 34. If the unstable zero is not repeated, Eq. 33 is the only interpolation condition that has to be met [37].

$$S(a\_x) = \mathbf{1}, \ T(a\_x) = \mathbf{0} \tag{33}$$

$$\frac{d^k S}{ds^k}(a\_\mathbf{z}) = \mathbf{0}, \ \frac{d^k T}{ds^k}(a\_\mathbf{z}) = \mathbf{0}, \qquad \text{For} \qquad \mathbf{1} \le k \le n \tag{34}$$

If all the conditions above are met, then we can obtain the controller using Eq. 35.

$$G\_{\mathfrak{c}}(\mathfrak{s}) = Y(\mathfrak{s}) \cdot \mathbb{S}(\mathfrak{s})^{-1} \tag{35}$$

In the following subsections, we discuss the controller design for the proposed brake actuators using the above strategy known as Youla parameterization.

#### **3.2 EHB Youla control design**

For the first step, we should acquire EHB's plant transfer function from the pressure input to the clamp force exerted on the wheel, which can be derived from Eqs. 5–9. However, using bond graph and equivalent mass *mEq* and resistance

*bEq* � �, we can further simplify the equations and the transfer function to a lower degree. The equivalent mass and resistance are defined in the Eqs. 36 and 37 [33].

$$m\_{Eq} = m\_w + A\_w^2 \cdot I\_{line} \tag{36}$$

$$b\_{Eq} = b\_w + A\_w^2 \cdot R\_{line} \tag{37}$$

The transfer function from the input pressure to the clamp force can be written as (Eq. 38).

$$G\_{P\_{E\text{HB}}} = \frac{F\_{cl}}{P\_{in}} = \frac{k\_{cal} \cdot A\_w}{m\_{Eq}s^2 + b\_{Eq}s + k\_{cal}}\tag{38}$$

Since the plant is stable and does not contain any unstable poles or non minimum phase zeros, no interpolation conditions need to be satisfied except selecting a stable Youla transfer function. We have selected this transfer function such that all of the plant's poles are canceled in order to freely shape the closed loop transfer function *T s*ð Þ and then compute this closed loop transfer function from Eq. 29. We choose the closed loop transfer function to be a second order Butterworth filter (Eq. 40) since this filter shape is optimal and we can freely choose the bandwidth and crossover frequencies. Additionally, we can add a low pass filter to Youla parameter to force it to be small in magnitude at high frequencies as we mentioned in the Section 3.1. This will result in Eqs. 39 and 40. By having T and Y, we can compute the controller using Eqs. 30 and 35. Since this process is the same in all the control designs, from now on, we only calculate Y and T for each loop. The sensitivity transfer function, S, can be computed from T (Eq. 30) and the controller transfer function, ð Þ *Gc* , can be computed using Eq. 35.

$$Y\_{EHB} = G\_{p\_{EHB}}^{-1} \cdot \frac{\alpha\_n^2}{s^2 + 2\alpha\_n \underline{\varepsilon} \cdot s + \alpha\_n^2} \cdot \frac{W\_1}{s + W\_1} = \frac{\alpha\_n^2}{k\_{cal} \cdot A\_w} \cdot \frac{m\_{Eq}s^2 + b\_{Eq}s + k\_{cal}}{s^2 + 2\alpha\_n \underline{\varepsilon} \cdot s + \alpha\_n^2} \cdot \frac{W\_1}{s + W\_1} \tag{39}$$

$$T\_{EHB} = \frac{\alpha\_n^2}{s^2 + 2\alpha\_n \underline{\varepsilon} \cdot s + \alpha\_n^2} \cdot \frac{W\_1}{s + W\_1} \tag{40}$$

We now have two control parameters to tune: *<sup>ω</sup>n*, and *<sup>W</sup>*<sup>1</sup> (*<sup>ξ</sup>* is selected to be <sup>1</sup>ffiffi 2 p for a second order Butterworth filter). We can choose the natural frequency of the Butterworth filter ð Þ *ω<sup>n</sup>* based on the closed loop bandwidth requirement. In addition, using rule of thumb, we select *W*<sup>1</sup> to be at least five times bigger that the closed loop bandwidth so that the pole location associated with this transfer function would have no impact on the closed loop bandwidth. **Figure 11** shows a Bode magnitude plot of the T, S and Y based on the proposed control design.

**Figure 12** shows the time response of the EHB closed and open loops. The openloop pressure input is 3.2 kPa (this is chosen to generate the same steady-state results as the closed-loop controller) and the closed-loop is set to follow a 8 kN clamp force target. As shown in **Figure 12**, the controller is capable of following the target well and eliminates the open-loop overshoot.

#### **3.3 EMB Youla control design**

Since we have a cascaded control strategy for the EMB actuator, we are required to design three controllers. We start from the inner loop (current control), and the second loop (angular velocity of the shaft), and lastly we make our way up to the most outer loop which is clamp force control.

**Figure 11.** *EHB's designed closed-loop transfer function T*ð Þ*, Youla transfer function (Y), and sensitivity transfer function S*ð Þ*.*

**Figure 12.** *EHB's controller results - closed loop vs. open loop.*

*New Robust Control Design of Brake-by-Wire Actuators DOI: http://dx.doi.org/10.5772/intechopen.94581*

Using Eq. 10, we can calculate the transfer function from the voltage input to the output current. However, we are regarding the last term in the equation *Kt* ð Þ � *ω<sup>m</sup>* as a disturbance. The idea is to divide the bond graph into three separate blocks and control each block using the cascaded control strategy. This approach would make the design simpler and more intuitive so that any inputs from other blocks are regarded as disturbances. In this case, the input signal from the gyrator in **Figure 6** is regarded as a disturbance. We can then write the transfer function as Eq. 41.

$$G\_{p\_{EMB}} = \frac{I\_m}{V\_{in}} = \frac{\frac{1}{L\_m}}{s + \frac{R\_m}{L\_m}}\tag{41}$$

Since *GpEMB* has no unstable pole and non-minimum phase zero, we can cancel all the plant poles and create the desired closed loop response. However, canceling all the poles would result in a bigger magnitude of Youla transfer function; therefore, higher actuation effort. Since we want to keep the actuator effort as low as possible, we are going to only use a low-pass filter for Youla transfer function. In this design, we select the Youla transfer function such that the closed loop transfer function *T* has the same bandwidth as the original plant. The selected Youla transfer function is given by Eq. 42. Based on *YEMB*<sup>1</sup> , we can compute *TEMB*<sup>1</sup> which is shown in Eq. 43. Another important note, when designing cascaded controllers, is that the closedloop bandwidth of the inner loop has to be always faster than its outer loop. This ensures that the inner loop follows any command changes of the outer loop and hence, the overall closed loop stability is not compromised.

$$\mathbf{Y}\_{\text{EMB}\_1} = \frac{\mathbf{1}}{\mathbf{G}\_{p\_{\text{EMB}\_1}}(\mathbf{0})} \cdot \frac{\mathbf{W}\_1}{\mathbf{s} + \mathbf{W}\_1} = R\_m \cdot \frac{\mathbf{W}\_1}{\mathbf{s} + \mathbf{W}\_1} \tag{42}$$

$$T\_{EMB\_1} = R\_m \cdot \frac{W\_1}{s + W\_1} \cdot \frac{1}{L\_m s + R\_m} \tag{43}$$

**Figure 13a** shows that the magnitude of Youla transfer function reduces at high frequency while T and S have their desired shapes.

The controller for the second loop will be designed next. In this case, the new plant to is the inner loop closed-loop transfer function ð Þ *TEMB* multiplied by the transfer function from the second block open loop related to the dynamics of angular velocity of the shaft. The dynamics of the second block can be derived from Eq. 11 by considering the last term as the disturbance and substituting the nonlinear friction with a linear one *τ <sup>f</sup>* ¼ *Dm* � *ω<sup>m</sup>* . This results in Eq. 44, and transfer functions *YEMB*<sup>2</sup> and *TEMB*<sup>2</sup> are given by Eqs. 45 and 46 respectively.

$$G\_{EMB\_2} = T\_{EMB\_1} \cdot \frac{\alpha\_m}{I\_m} = T\_{EMB\_1} \cdot \frac{\frac{K\_t}{I\_m}}{s + \frac{D\_m}{I\_m}} \tag{44}$$

$$\mathbf{Y}\_{EMB\_2} = \frac{1}{\mathbf{G}\_{EMB\_2}(\mathbf{0})} \cdot \frac{W\_2}{s + W\_2} = \frac{D\_m}{K\_t} \cdot \frac{W\_2}{s + W\_2} \tag{45}$$

$$T\_{EMB\_2} = D\_m \cdot \frac{W\_2}{s + W\_2} \cdot \frac{W\_1}{s + W\_1} \cdot \frac{1}{J\_m s + D\_m} \cdot \frac{R\_m}{L\_m s + R\_m} \tag{46}$$

For the last loop, the transfer function from *ω<sup>m</sup>* to *F*C*<sup>l</sup>*, the same procedure as the last loop is utilized to compute the open loop transfer function (Eq. 47). As shown in Eq. 47, there is a pole at zero. This pole must be canceled by Youla transfer function to meet the interpolation conditions ð*T*ð Þ¼ 0 1 and *S*ð Þ¼ 0 0Þ, hence,

#### **Figure 13.**

*EMB's designed closed-loop transfer function T*ð Þ*, Youla transfer function (Y), and sensitivity transfer function* ð Þ*S for the current, ω and force control loop. (a) Current control bodes, (b) angular velocity control bodes, and (c) force control bodes.*

to ensure internal stability. Finally, the transfer functions *YEMB*<sup>2</sup> and *TEMB*<sup>2</sup> are given by Eqs. 48 and 49 respectively. The Bode plots are equivalently shown in **Figure 13b** and **c**.

*New Robust Control Design of Brake-by-Wire Actuators DOI: http://dx.doi.org/10.5772/intechopen.94581*

$$G\_{\rm EMB\_3} = T\_{\rm EMB\_2} \cdot \frac{F\_{\rm cal}}{\alpha\_m} = T\_{\rm EMB\_2} \cdot \frac{K\_{\rm cal} \cdot N\_{\rm s} \cdot N\_p}{\mathfrak{s}} \tag{47}$$

$$Y\_{EMB\_3} = \frac{s}{G\_{EMB\_3} \cdot s(\mathbf{0})} \cdot \left(\frac{W\_3}{s + W\_3}\right)^2 = \frac{s}{K\_{cd} \cdot N\_s \cdot N\_p} \cdot \left(\frac{W\_3}{s + W\_3}\right)^2\tag{48}$$

$$T\_{EMB\_3} = G\_{EMB\_3} \cdot Y\_{EMB\_3} = \left(\frac{W\_3}{\varepsilon + W\_3}\right)^2 \cdot \frac{W\_2}{\varepsilon + W\_2} \cdot \frac{W\_1}{\varepsilon + W\_1} \cdot \frac{D\_m}{J\_m\varepsilon + D\_m} \frac{R\_m}{L\_m\varepsilon + R\_m} \tag{49}$$

#### **3.4 EWB Youla control design**

For this actuator, we follow the same procedure as the EMB and Eqs. 50–58 are the results of this control design process. **Figure 14** shows the magnitude Bode plots of the closed loop transfer functions for the current, angular velocity of the shaft, and clamp force, respectively.

$$G\_{P\_{EWB\_1}} = \frac{I\_m}{V\_{in}} = \frac{\frac{1}{L\_m}}{s + \frac{R\_m}{L\_m}}\tag{50}$$

$$\mathbf{Y}\_{EWB\_1} = \frac{1}{\mathbf{G}\_{p\_{EW\_1}}(\mathbf{0})} \cdot \frac{W\_1}{s + W\_1} = R\_m \cdot \frac{W\_1}{s + W\_1} \tag{51}$$

$$T\_{EWB\_1} = R\_m \cdot \frac{W\_1}{s + W\_1} \cdot \frac{1}{L\_m s + R\_m} \tag{52}$$

$$G\_{EWB\_2} = T\_{EWB\_1} \cdot \frac{\alpha\_m}{I\_m} = T\_{EWB\_1} \cdot \frac{\frac{K\_t}{J\_m}}{s + \frac{D\_m}{I\_m}} \tag{53}$$

$$Y\_{EWB\_2} = \frac{1}{G\_{EWB\_2}(\mathbf{0})} \cdot \frac{W\_2}{\varepsilon + W\_2} = \frac{D\_m}{K\_t} \cdot \frac{W\_2}{\varepsilon + W\_2} \tag{54}$$

$$T\_{EWB\_2} = D\_m \frac{W\_2}{s + W\_2} \frac{W\_1}{s + W\_1} \frac{1}{f\_m s + D\_m} \frac{R\_m}{L\_m s + R\_m} \tag{55}$$

$$G\_{EWB\_3} = T\_{EWB\_2} \frac{F\_{cal}}{\alpha\_m} = T\_{EWB\_2} \cdot K\_{cal} \cdot \sin\left(a\right) \frac{L \cdot N}{2\pi} \cdot \frac{1}{s} \cdot \frac{D\_{ax}s + K\_{ax}}{m\_w s^2 + D\_{ax}s + K\_{cal} \sin^2 a + K\_{ax}} \tag{56}$$

$$Y\_{EWB\_3} = \frac{s}{G\_{EWB\_3} \cdot s(\mathbf{0})} \cdot \left(\frac{W\_3}{s + W\_3}\right)^2 = \frac{2\pi \cdot \left(K\_{cal} \cdot \sin^2 a + K\_{ax}\right)}{K\_{cal} \cdot L \cdot N \cdot K\_{ax} \sin a} \cdot s \cdot \left(\frac{W\_3}{s + W\_3}\right)^2\tag{57}$$

$$T\_{EWB\_3} = Y\_{EWB\_3} \cdot G\_{EWB\_3}$$

$$\begin{aligned} \mathbf{I}\_{1} &= \left(\frac{\mathcal{W}\_{3}}{\mathfrak{s} + \mathcal{W}\_{3}}\right)^{2} \frac{\mathcal{W}\_{2}}{\mathfrak{s} + \mathcal{W}\_{2}} \frac{\mathcal{W}\_{1}}{\mathfrak{s} + \mathcal{W}\_{1}}. \\\\ \frac{D\_{m}}{J\_{m}\mathfrak{s} + D\_{m}} & \cdot \frac{R\_{m}}{L\_{m}\mathfrak{s} + R\_{m}} \cdot \frac{K\_{cal}\sin^{2}\mathfrak{a} + K\_{\text{ax}}}{K\_{\text{ax}}} \cdot \frac{D\_{\text{ax}}\mathfrak{s} + K\_{\text{ax}}}{m\_{\text{w}}\mathfrak{s}^{2} + D\_{\text{ax}}\mathfrak{s} + K\_{\text{cal}}\sin^{2}\mathfrak{a} + K\_{\text{ax}}}. \end{aligned} \tag{58}$$

#### **3.5 Disturbance rejection**

In our previous cascaded control strategy, we ignored the disturbance terms in each loop. However, these disturbance still have a negative impact on each loop's performance. Therefore, we are interested in looking at how each of these

**Figure 14.**

*EWB's designed closed-loop transfer function T*ð Þ*, Youla transfer function (Y), and sensitivity transfer function* ð Þ*S for the current, angular velocity of the shaft, and force control loop. (a) Current control bodes, (b) angular velocity control bodes, and (c) force control bodes.*

disturbances play a role in the loop. To analyze the effect of disturbances, we need to obtain the disturbance input to the loop output transfer function in each case. This would also help in design a feed-forward disturbance rejection to mitigate the negative effect of disturbances on the output and actuator effort. **Figure 10** shows a *New Robust Control Design of Brake-by-Wire Actuators DOI: http://dx.doi.org/10.5772/intechopen.94581*

block diagram where the disturbances in the cascaded control loop are given. To mitigate the effect of disturbance in each loop, a feed-forward term is added to reject these disturbances, as shown in **Figure 15**. For the sake of simplicity, the disturbance rejections have not been shown in all the cascaded loops. This disturbance rejection technique can be used wherever the disturbance can be estimated as these disturbance signals cannot be directly measured. Since the estimation might be computationally expensive and not very accurate at times, we should only use disturbance rejection wherever there is a great negative impact on closed loop the performance or on the actuator effort. The effect of the disturbance rejection is shown in Eq. 59 by additional term �*Gpd G*�<sup>1</sup> *<sup>p</sup> S*

$$\mu = \left(-\mathbf{G}\_{p\_d} \cdot \mathbf{G}\_p^{-1} \mathbf{S} - \mathbf{Y} \cdot \mathbf{G}\_{p\_d}\right) \cdot \mathbf{F}\_d + \mathbf{Y} \cdot \mathbf{r} \tag{59}$$

**Figure 16** shows the time response of the current loop for a step function of 5 A. As shown, the disturbance rejection has a faster response while maintaining the same level of actuation. It has slightly increases the actuator effort; however, since the closed loop time response with the disturbance rejection is faster, the feedback control loop bandwidth can be reduced to produce the similar time response

**Figure 15.** *Block diagram of disturbance rejection scheme used in the cascaded controller loops for EMB/EWB.*

**Figure 16.** *EMB's current control step time response with and without the disturbance rejection.*

**Figure 17.** *EMB's angular velocity control pulse response with and without the disturbance rejection.*

without the feed-forward term. This way we can reduce the actuation effort. **Figure 17** shows the response of the second loop to a pulse function of 200 *rad sec* including the current disturbance rejection capability. This shows that disturbance rejection has a big effect on the steady-state value. Finally, **Figure 18**, shows the result of the actuator's response for a 10-kN clamp force reference. As discussed, when the disturbance rejection scheme is utilized, the closed loop response of the EMB actuator is faster (0.35 seconds vs. 0.8 seconds) while maintaining around the same level of actuation. It should be noted that all the time response simulations are based on nonlinear models. Nonlinearity includes both frictions and actuator

**Figure 18.** *EMB's closed-loop response over a step function with and without the disturbance rejection.*

**Figure 19.** *EWB's current control step time response with and without the disturbance rejection.*

saturation limits on the caliper for EMB actuator and only saturation limits for EWB actuator. Future studies will include addition of non-linear frictions to EWB.

**Figures 19**–**21** show the results for the EWB actuator disturbance rejection performances. As shown in **Figure 19**, the disturbance rejection has a great impact on the current control responsiveness while maintaining the same amount of voltage. However, **Figures 20** and **21** show that the second and third loop's disturbance rejections do not have much of impacts on the either closed- loop responses or

**Figure 20.** *EWB's angular velocity control pulse response with and without the disturbance rejection.*

**Figure 21.** *EWB's closed-loop response over a step function with and without the disturbance rejection.*

actuator efforts; therefore, it is recommended, in this case, to only use the current control feedforward disturbance rejection capability and abandon the other disturbance rejections in the second and the third loops.

#### **4. Conclusions**

In this chapter, we modeled three different friction brake-by-wire actuators using bond graph method. We then designed closed loop feedback controllers for each actuator using Youla parameterization technique. For the EMB and EWB actuators, we used a cascaded control strategy. Additionally, we designed disturbance rejections for each of their loops. The results of these disturbance rejections were discussed and it was found that EHB has a fastest response compared with the EMB and EWB actuators. However, this comes at higher cost due to addition of hydraulic lines and modules. When comparing the EMB and EWB actuators, based on the given current tuning, EWB has a faster response than the EMB, however, EWB also requires a higher actuator effort. Further investigation is required, by simultaneous optimization of actuators' physical systems including their control parameters, to have a better comparative analysis of the proposed actuators.

Other future studies will include more complex models where additional of some missing physical components (such as hydraulic pump, accumulator, and hydraulic build and dump valves) would be necessary to improve the accuracy of our comparative results. Additionally, a reference trajectory generator can be added, such as [38], to compare the performance of the proposed actuators during an ABS maneuver.

#### **Acknowledgements**

Authors would like to thank Louis Filipozzi and Kevin R. Mallon for their comments and review of this book chapter.

*New Robust Control Design of Brake-by-Wire Actuators DOI: http://dx.doi.org/10.5772/intechopen.94581*
