#### 2.4.2 Adaptive modeling of disturbance {#2-dot-4-dot-2-adaptive-modeling-of-disturbance}
### 2.5 Conclusion {#2-dot-5-conclusion}
## 3. Modeling of [Stewart Platforms]({{< relref "stewart_platforms" >}}) {#3-dot-modeling-of-stewart-platforms--stewart-platforms-dot-md}
### 3.1 Introduction {#3-dot-1-introduction}
### 3.2 System description and governing equations {#3-dot-2-system-description-and-governing-equations}
### 3.3 Modeling using adaptive filtering approach {#3-dot-3-modeling-using-adaptive-filtering-approach}
#### 3.3.1 Adaptive filtering theory {#3-dot-3-dot-1-adaptive-filtering-theory}
#### 3.3.2 Modeling of a Stewart platform {#3-dot-3-dot-2-modeling-of-a-stewart-platform}
### 3.4 Conclusion {#3-dot-4-conclusion}
## 4. Classical Vibration Control {#4-dot-classical-vibration-control}
### 4.1 Introduction {#4-dot-1-introduction}
### 4.2 Passive control {#4-dot-2-passive-control}
#### 4.2.1 Isolators {#4-dot-2-dot-1-isolators}
#### 4.2.2 Absorbers {#4-dot-2-dot-2-absorbers}
#### 4.2.3 Resonators {#4-dot-2-dot-3-resonators}
#### 4.2.4 Suspension {#4-dot-2-dot-4-suspension}
#### 4.2.5 An application example – Disk vibration reduction via stacked disks {#4-dot-2-dot-5-an-application-example-and-8211-disk-vibration-reduction-via-stacked-disks}
### 4.3 Self-adapting systems {#4-dot-3-self-adapting-systems}
### 4.4 Active vibration control {#4-dot-4-active-vibration-control}
#### 4.4.1 Actuators {#4-dot-4-dot-1-actuators}
#### 4.4.2 Active systems {#4-dot-4-dot-2-active-systems}
#### 4.4.3 Control strategy {#4-dot-4-dot-3-control-strategy}
### 4.5 Conclusion {#4-dot-5-conclusion}
## 5. Introduction to Optimal and Robust Control {#5-dot-introduction-to-optimal-and-robust-control}
### 5.1 Introduction {#5-dot-1-introduction}
### 5.2 H2 and H∞ norms {#5-dot-2-h2-and-h-and-8734-norms}
#### 8.4.2 Phase lead peak filter {#8-dot-4-dot-2-phase-lead-peak-filter}
#### 8.4.3 Group peak filter {#8-dot-4-dot-3-group-peak-filter}
### 8.5 Application in high frequency vibration rejection {#8-dot-5-application-in-high-frequency-vibration-rejection}
### 8.6 Application in mid-frequency vibration rejection {#8-dot-6-application-in-mid-frequency-vibration-rejection}
### 8.7 Conclusion {#8-dot-7-conclusion}
## 9. Combined H2 and KYP Lemma-Based Control Design {#9-dot-combined-h2-and-kyp-lemma-based-control-design}
### 9.1 Introduction {#9-dot-1-introduction}
### 9.2 Problem formulation {#9-dot-2-problem-formulation}
### 9.3 Controller design for specific disturbance rejection and overall error minimization {#9-dot-3-controller-design-for-specific-disturbance-rejection-and-overall-error-minimization}
#### 9.3.1 Q parametrization to meet specific specifications {#9-dot-3-dot-1-q-parametrization-to-meet-specific-specifications}
#### 9.3.2 Q parametrization to minimize H2 performance {#9-dot-3-dot-2-q-parametrization-to-minimize-h2-performance}
### 9.4 Simulation and implementation results {#9-dot-4-simulation-and-implementation-results}
#### 9.4.1 System models {#9-dot-4-dot-1-system-models}
#### 9.4.2 Rejection of specific disturbance and H2 performance minimization {#9-dot-4-dot-2-rejection-of-specific-disturbance-and-h2-performance-minimization}
#### 9.4.3 Rejection of two disturbances with H[sub(2)] performance minimization {#9-dot-4-dot-3-rejection-of-two-disturbances-with-h-sub--2--performance-minimization}
### 9.5 Conclusion {#9-dot-5-conclusion}
## 10. Blending Control for Multi-Frequency Disturbance Rejection {#10-dot-blending-control-for-multi-frequency-disturbance-rejection}
### 10.1 Introduction {#10-dot-1-introduction}
### 10.2 Control blending {#10-dot-2-control-blending}
#### 10.2.1 State feedback control blending {#10-dot-2-dot-1-state-feedback-control-blending}
#### 10.2.2 Output feedback control blending {#10-dot-2-dot-2-output-feedback-control-blending}
### 10.3 Control blending application in multi-frequency disturbance rejection {#10-dot-3-control-blending-application-in-multi-frequency-disturbance-rejection}
#### 10.3.1 Problem formulation {#10-dot-3-dot-1-problem-formulation}
#### 10.3.2 Controller design via the control blending technique {#10-dot-3-dot-2-controller-design-via-the-control-blending-technique}
### 10.4 Simulation and experimental results {#10-dot-4-simulation-and-experimental-results}
<aid="orge4a6b7f"></a>Du, Chunling, and Lihua Xie. 2010. _Modeling and Control of Vibration in Mechanical Systems_. Automation and Control Engineering. CRC Press. <https://doi.org/10.1201/9781439817995>.