Skip to main content

Feedforward Control System

Published Date
Author Cadence PCB Solutions

Key Takeaways

  • A feedforward control system improves system performance by taking preemptive action based on known or anticipated disturbances rather than reacting to the system's output.

  • A feedforward control system requires accurate models of the system and disturbances, which can be challenging to develop and may also be ineffective when dealing with unmodeled or unpredictable disturbances.

  • PCB designers need to plan for the specific requirements of the feedforward control system, the accuracy of measurements, and the reliability of data acquisition and processing components.

Graphic representation of a feedforward control system

In a feedforward control system, advance information is used to calculate the necessary control signal that will lead to the desired output.

A feedforward control system improves system performance by taking preemptive action based on known or anticipated disturbances rather than reacting to the system's output. It directly manipulates the system's input based on a model or prediction of how disturbances will impact the output. By preemptively adjusting the input to counteract anticipated disturbances, a feedforward controller boosts the system's overall accuracy, stability, and response time, making it a valuable tool in various industrial applications, such as manufacturing, robotics, and process control.

Feedforward Control System: Advantages and Disadvantages

Advantages

Disadvantages

Acts before the system is affected by the disturbance

Requires accurate system modeling and disturbance measurement

Rapid response to disturbances

Difficulty handling random or unforeseen disturbances

Greater accuracy for known disturbances

Complex tuning requirements

Avoids overcorrection 

Noise in sensors used for measurement reduces effectiveness

How Does a Feedforward Control System Work?

Incorporating feedforward control into a system can achieve faster response times, reduced oscillations, and better overall performance. However, a feedforward control system requires accurate models of the system and disturbances, which can be challenging to develop. It may also be ineffective when dealing with unmodeled or unpredictable disturbances. 

A feedforward control system works in the following ways:

  • Detection and Measurement: The system first detects and measures a disturbance or change in the input likely to affect the system's performance. External factors, such as temperature variations, load changes, or other environmental conditions, can cause this disturbance.

  • Prediction: Using mathematical models or historical data, the feedforward control system predicts how the disturbance will affect the system's output. This prediction is based on cause-and-effect relationships between the disturbance and the system's response.

  • Compensation: The feedforward control system generates a control action that counteracts the predicted disturbance. This control action mitigates the disturbance's effects and maintains the desired system output.

  • Feedback Control: Besides the feedforward control action, the system may also employ a feedback control loop. This loop continuously monitors the actual system output and adjusts the control action as necessary to ensure that the system remains on target.

In many applications, a combination of feedforward and feedback control is used to achieve the best overall performance. With feedforward control, known disturbances are mitigated and system performance is optimized, reducing response times and errors. On the other hand, feedback control adapts to unanticipated disturbances and uncertainties in real time. Through the combination of these approaches, the system is capable of handling a range of operating conditions and disturbances while minimizing control effort and energy consumption.

Feedforward Control System and PCB Design

In the context of PCB design, a feedforward control system doesn't directly affect the physical design of the PCB layout. Still, it can affect the function and performance of the electronic system in which the PCB is embedded. Here are some PCB design considerations for feedforward control systems:

  • Data Acquisition and Processing: Feedforward control systems often require real-time data acquisition and processing to make predictions and generate control signals by incorporating microcontrollers, digital signal processors, or dedicated analog or digital circuits on the PCB. The placement and design of these components are critical for efficient data processing and communication.

  • Signal Conditioning and Filtering: In a feedforward control system, accurately measuring and conditioning input signals to predict the system's behavior is essential. A PCB designer should incorporate signal conditioning circuits, amplifiers, filters, or sensors to ensure the input signals are accurate and noise free.

  • Interfacing and Communication: PCBs in feedforward control systems may need to interface with other components or systems, such as sensors, actuators, or central controllers. The PCB design must consider the compatibility of communication protocols, voltage levels, and signal interfaces.

  • Component Selection: Choosing the right components, including sensors, amplifiers, microcontrollers, and other integrated circuits, is essential to the success of a feedforward control system. Component selection should consider factors like accuracy, speed, and reliability.

  • Noise Mitigation: Since feedforward control systems rely on accurate measurements, minimizing electromagnetic interference and ensuring signal integrity on the PCB is crucial. PCB designers should incorporate proper grounding and shielding, and carefully route sensitive traces can be essential.

  • Power Supply: Feedforward control systems may have specific power requirements to ensure stable and reliable operation. The PCB designer should account for power distribution, voltage regulation, and noise filtering to provide critical components with a clean and stable power supply.

  • Testing and Verification: PCBs should be rigorously tested and verified to meet required performance specifications, including functional testing, signal quality testing, and validation against expected control system behavior.

A feedforward control system influences the PCB's design considerations and component choices. Designers need to plan for the specific requirements of the feedforward control system, the accuracy of measurements, and the reliability of data acquisition and processing components when designing the PCB to ensure that it operates effectively within the control system's framework.

Cadence Has the PCB Design Tools You Need 

PCB designers can include the requirements of feedforward control systems in their designs when they have access to the best PCB design and analysis software. Cadence has the software and tools, such as its ORCAD PCB Designer, to successfully account for feedforward and feedback control systems in PCB design. 

Leading electronics providers rely on Cadence products to optimize power, space, and energy needs for a wide variety of market applications. To learn more about our innovative solutions, talk to our team of experts or subscribe to our YouTube channel.