A Sensor-Aided System for Physical Perfect Control Applications in the Continuous-Time Domain
<p>The arrangement scheme of cascade multi-tank system [<a href="#B46-sensors-23-01947" class="html-bibr">46</a>].</p> "> Figure 2
<p>Scheme of the the two-level thermal object (source: authors).</p> "> Figure 3
<p>Geometry of the tank in which the water level was maintained—dimensions given in cm (source: authors).</p> "> Figure 4
<p>Control process of the filling of the second tank (source: authors).</p> "> Figure 5
<p>Interior temperature control (source: authors).</p> "> Figure 6
<p>Graphical presentation of <a href="#sensors-23-01947-t001" class="html-table">Table 1</a> and <a href="#sensors-23-01947-t002" class="html-table">Table 2</a> (source: authors).</p> "> Figure 7
<p>The examined modular sensor-aided servomechanism (source: authors).</p> "> Figure 8
<p>Diagram of DC motor [<a href="#B47-sensors-23-01947" class="html-bibr">47</a>].</p> "> Figure 9
<p>Diagram of control system (source: authors).</p> "> Figure 10
<p>The received angular position of the model and the sensor-aided object—results of the three attempts with 100° reference value (source: authors).</p> "> Figure 11
<p>The received velocity of the model and the sensor-aided object for 100° reference value (source: authors).</p> "> Figure 12
<p>The received angular position of the model and the sensor-aided object—results of the three attempts with 300° reference value (source: authors).</p> "> Figure 13
<p>The received velocity of the model and the sensor-aided object for 300° reference value (source: authors).</p> "> Figure 14
<p>The received angular position of the the sensor-aided object for 100° reference value (source: authors).</p> "> Figure 15
<p>The received angular position of the the sensor-aided object for 300° reference value (source: authors).</p> "> Figure 16
<p>Graphical presentation of <a href="#sensors-23-01947-t004" class="html-table">Table 4</a> (source: authors).</p> ">
Abstract
:1. Introduction
2. System Representation
3. Preliminaries
3.1. Generalized -Inverse
3.2. Continuous-Time Perfect Control
3.3. The LQ Regulation
3.4. The LQR with Integrating Action
3.5. Systems under Consideration
3.5.1. The Cascade Multi-Tank System
3.5.2. The Two-Level Thermal Object
3.6. Quality Criteria
- ISE—Integral of Squared Error defined by
- MOE—Minimum of energy which is an integral of squared control signal
- RT—Regulation time which is a time considered from the beginning of the simulation to receiving the tolerance range of the expected value by the system output.
4. The Real Continuous-Time Perfect Control
5. Simulation Studies
5.1. The Cascade Multi-Tank System Control
5.2. The Two-Level Thermal Object Control
6. Discussion on the Obtained Simulation Results
7. The Sensor-Aided System—A Real experiment Setup
8. A Real Experiment on a Sensor-Aided Servomechanism
8.1. The First Experiment with the RCTPC Law
8.2. The Second Experiment with the RCTPC Law
8.3. Experiment with PID Regulator
9. Discussion on the Obtained Sensor-Aided System Control Results
10. Conclusions and Open Problems
Author Contributions
Funding
Institutional Review Board Statement
Informed Consent Statement
Data Availability Statement
Conflicts of Interest
Appendix A
Symbol | Description | Value | Unit |
---|---|---|---|
height of the first tank | 0.35 | m | |
height of the second tank | 0.35 | m | |
height of the third tank | 0.35 | m | |
cross-section of the first valve | m2 | ||
cross-section of the second valve | m2 | ||
cross-section of the third valve | m2 | ||
initial liquid height of the 1st tank | 0.12 | m | |
initial liquid height of the 2nd tank | 0.8 | m | |
initial liquid height of the 3rd tank | 0.15 | m | |
flow factor of the first tank | 0.5 | - | |
flow factor of the second tank | 0.5 | - | |
flow factor of the third tank | 0.5 | - | |
R | radius of the third tank | 0.365 | m |
a | the base of the first tank | 0.25 | m |
b | distance between tanks | 0.348 | m |
c | base of the second tank | 0.1 | m |
w | the width of all tanks | 0.035 | m |
set flow through the pump | (m3)/s | ||
q | liquid inlet to the upper tank | - | (m3)/s |
initial condition of liquid inlet | 0.035 | (m3)/s |
Symbol | Description | Value | Unit |
---|---|---|---|
interior temperature | - | °C | |
initial interior temperature | 0 | °C | |
exterior temperature | - | °C | |
initial exterior temperature | −20 | °C | |
attic temperature | - | °C | |
initial attic temperature | 0 | °C | |
heat power | - | W | |
initial heat power | 20,000 | W | |
interior thermal capacity | 25,714.29 | J/K | |
attic thermal capacity | 5714.29 | J/K | |
loss coefficient of the roof | 60 | - | |
loss coefficient of the external walls | 80 | - | |
loss coefficient of the ceiling | 50 | - |
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(m) | |||
(s) | |||
MOE (m3/s) |
(°C) | |||
(s) | |||
(W) |
Symbol | Description | Unit |
---|---|---|
input voltage | V | |
armature current | [A] | |
angular velocity of the rotor | [rad/s] | |
R | armature resistance | [Ω] |
damping factor | - | |
electromagnetic field | - |
RCTPC | 100 [°] | 300 [°] |
---|---|---|
[°] | ||
[°] | ||
[°] | ||
[s] | ||
[s] | ||
PID | 100 [°] | 300 [°] |
[°] | ||
[s] | ||
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Majewski, P.; Hunek, W.P.; Pawuś, D.; Szurpicki, K.; Wojtala, T. A Sensor-Aided System for Physical Perfect Control Applications in the Continuous-Time Domain. Sensors 2023, 23, 1947. https://doi.org/10.3390/s23041947
Majewski P, Hunek WP, Pawuś D, Szurpicki K, Wojtala T. A Sensor-Aided System for Physical Perfect Control Applications in the Continuous-Time Domain. Sensors. 2023; 23(4):1947. https://doi.org/10.3390/s23041947
Chicago/Turabian StyleMajewski, Paweł, Wojciech P. Hunek, Dawid Pawuś, Krzysztof Szurpicki, and Tomasz Wojtala. 2023. "A Sensor-Aided System for Physical Perfect Control Applications in the Continuous-Time Domain" Sensors 23, no. 4: 1947. https://doi.org/10.3390/s23041947
APA StyleMajewski, P., Hunek, W. P., Pawuś, D., Szurpicki, K., & Wojtala, T. (2023). A Sensor-Aided System for Physical Perfect Control Applications in the Continuous-Time Domain. Sensors, 23(4), 1947. https://doi.org/10.3390/s23041947