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"Quanser's
DC motor control trainer is a system which makes it possible
to demonstrate theory by practice in a very simple and time
effective way. The difference between Quanser and other systems
is the flexibility and simplicity in control, from pic micro
controllers and computational software (MATLAB) to analog
controllers made at home. At the design level, it is very
effective in testing and prototyping fuzzy control systems."
Mohammad Taha
Automatic Control And Signal Processing Engineer
Princess Sumaya University for Technology |
The QET DC Motor Control trainer is the first in the Quanser Engineering
Trainer (QET) Series. This is an exceptional new line of high quality
yet affordable standalone trainers that demonstrate control fundamentals
using a wide range of control methods.
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The QET DC
Motor Control Trainer provides an ideal way to demonstrate
the fundamentals of motor control, tuning and haptics. This
affordable standalone trainer is exceptionally versatile and
can be controlled via analog, digital, embedded or computer
control. |
QET DC Motor Control trainer comes bundled with comprehensive
curriculum
materials co-developed with Professor Karl Åström. These
provide unsurpassed value for money.
- Curriculum co-developed with Professor Karl Åström covers:
- Modelling
- Speed Control
- Position Control
- Haptics
- Course materials for core experiments, making lesson & lab planning
effortless
- Plug-and-play design enables quick & easy lab setup
- No additional hardware or software required
- PIC-based real-time controller
- QIC interactive interfaces (QICii)
- Pre-compiled QIC controller available
- PC-based Java interface
- Compact design, easy to store
- Flexible control method
- analog (with supplied breadboard)
- digital (with external Data Acquisition Board & Software)
- embedded (with supplied PIC microcontroller)
- High quality DC graphite brush motor
- Linear amplifier
- Analog tachometer
- High resolution quadrature optical encoder mounted on motor
- Feedback potentiometer
- Position & Speed Control
- Disturbance Rejection
- Tracking Control & Regulation
- PID Controller Design
- Lead / Lag Compensation
- State-Feedback
- System Modeling & Simulation
- Frequency Analysis
- Phase & Gain Margin
- Root Locus Design
- Nyquist Stability
- Hardware-in-the-Loop
- Discrete Time Sampling
- System Identification
- Multivariable Control Design
- DC Motor Control
- Future QET Trainers for Mechatronics, Electrical Engineering, Mechanical
Engineering coming soon
