Introduction to Aspen DMCplus for APC Engineers

Learn how to develop and build control models and applications, and perform off-line tuning and simulation. Learn how to use the SmartStep mode of Aspen DMCplus. Develop skills to carry out Aspen DMCplus control projects and troubleshooting and maintaining Aspen DMCplus controllers.

This course is a combination of APC120: Introduction to aspenONE Advanced Process Control - Operating and Maintaining Controllers Online, and APC121: Introduction to Aspen DMCplus - Modeling and Building Controllers for Industrial Processes.

Audience:

Engineers who are maintaining existing Aspen DMCplus controllers
Description of the theoretical concepts that form the basis of the Aspen DMCplus family of products
Engineers who are designing or implementing new Aspen DMCplus controllers
Operating supervisors and console operators who are involved in Aspen DMCplus control projects

Training Details

Course Id:

APC101
Duration:

5 day(s)
CEUs Awarded:

3.5
Level:

Introductory

Benefits

Acquire the skills and knowledge required to participate on or lead a team charged with the development and deployment of an Advanced Process Control application
Acquire the skills and knowledge required to use and maintain Aspen DMCplus and Aspen DMC3 controllers
Know how to use DMCplus Model to identify a controller model before implementing the controller online
Increased effectiveness in basic troubleshooting of Aspen DMCplus and Aspen DMC3 controllers
Increased awareness of the operating characteristics and capabilities of Aspen DMCplus and Aspen DMC3 controllers

Approach

Introduction to basic concepts behind multivariable control
Demonstrations of the ways in which the online tools are used
Hands on workshops that allow operating and troubleshooting a typical Aspen DMCplus and Aspen DMC3 controller

Pre-requisites

Background in chemical process engineering and/or process operations Some familiarity with Microsoft® Windows operating systems

Subsequent Courses

This course serves as a prerequisite for many of the more advanced courses.

APC170 Introduction to Aspen Inferential Qualities - Developing and Deploying Inferential Soft Sensors for Industrial Processes
APC210 Aspen Watch Performance Monitor: Real Time Monitoring and Maintaining Controllers Online
APC230 Aspen DMCplus: APC Project Pretesting Using a Virtual Plant
APC240 Aspen DMCplus: APC Project Step Testing and Commissioning Using a Virtual Plant
APC250 Aspen DMC3: APC Calibrate and Aspen Adaptive Modeling

Agenda

Basic Concepts

Differentiate between Real Time Optimization and Advanced Control
Understand the use cases for APC
Learn about various AspenTech APC solutions
Workshop: Democol Manual Operation

Control Terminology

Review the definition of independent and dependent variables
Review the definitions of a Unit Response Curve, Time to Steady State and Steady State Gain
Review the defining characteristics of Aspen DMCplus and Aspen DMC3 Models and Controllers
Define a subcontroller

Production Control Web Server (PCWS)

Learn how to use PCWS to interact with the controller
Workshop: Democol Operation with Aspen DMCplus and Aspen DMC3 controller

APC Infrastructure

Learn about the APC Infrastructure

Models of Aspen DMCplus and Aspen DMC3 controllers

Introduction to the concept of plant test and different plant step test method
Learn about Aspen DMCplus and Aspen DMC3 modeling procedures
Workshop: Model Review

Aspen DMCplus Engine

Learn about the three modules in an Aspen DMCplus and Aspen DMC3 Engine
Learn which tuning parameters are used in each of the modules
Workshop: Democol tuning

Aspen DMCplus Controller Online Troubleshooting

Learn how to troubleshoot typical problems with an Aspen DMCplus or Aspen DMC3 online controller

DMC3 New Features

Introduction to new features in Aspen DMC3
Workshop: Democol Troubleshooting

Modeling Terminology

Differentiate between Real Time Optimization and Advanced Control
Discuss the characteristics of an independent variable and a dependent variable
Review the definitions of a Unit Response Curve, Time to Steady State, and Steady State Gain
Review the defining characteristics of an Aspen DMCplus Controller and the components comprising an Aspen APC Suite
Introduction to Aspen DMC3

APC Project Overview

Review the process for implementing an APC project
Discuss available alternatives and proper documentation procedures

Dynamic Modeling of Linear Systems

Review the definition of a dynamic, empirical, linear model and the technology of Finite Impulse Response (FIR) Modeling
Discuss the strengths and drawbacks of an FIR model

Model Identification using DMCplus Model

Familiarization with the DMCplus Model interface
Use the vector import tool to bring data into DMCplus Model
Review vector quality and perform data processing
Define and run model identification cases
Workshop: Fractionator Controller - Build a finite impulse response model for a simple fractionator

Model Analysis in DMCplus Model

Define and Run Predictions
Understand and use model analysis tools
Workshop: Fractionator Controller - Evaluate and assemble the model
Workshop: Fractionator Controller - Fix collinearity issues in the model

Variable Transformations

Configure built in transforms to deal with non-linear data
Configure transforms to rescale data
Workshop: Fractionator Controller - Apply variable transformation

SubSpace Identification Technology

Review modeling technology for MPC control
Subspace Identification: fundamentals and features
Aspen DMCplus - guidelines for Subspace modeling
Workshop: Fractionator Controller - Build a subspace model for the fractionator

Open Loop Prediction

Learn how DMCplus uses the dynamic model to predict the future behavior of controlled variables
Learn how DMCplus accounts for differences between the prediction and the actual measurements
Learn how DMCplus corrects predictions for ramp variables
Learn how prediction errors can be used to assess modeling errors
Workshop: Fractionator Controller - Configure prediction error filter options

Steady-State Feasibility Check

Introduce the DMCplus Steady State Optimization features
Recognize how DMCplus uses the Steady State Predictions in Projecting the Optimum Operating Point for the Process
Differentiate between a Linear Program and a Quadratic Program

Economic Optimization

Determine how MV Costs can be used to drive the Process to an Economic Optimum
Determine how an external Optimizer can affect the DMCplus Steady State Solution
Workshop: Fractionator Controller - Calculating Steady State Cost and configuring the Steady State Optimizer

Minimizing Dynamic Errors

Introduce DMCplus Dynamic Move Calculations features
Discuss how computing multiple future moves improves control
Understand tradeoffs between move aggressiveness and error minimization
Explain how ramps are controlled dynamically
Review details of the Move Calculation

Using DMCplus Build and DMCplus Simulate

Build Controller Configuration Files (CCF) using DMCplus Build
Write custom calculations using DMCplus Build
Review tuning and simulate controller operation using DMCplus Simulate
Workshop: Fractionator Controller - Configure the CCF file using DMCplus Build
Workshop: Fractionator Controller - Dynamic Tuning to adjust move suppressions to achieve smooth control

Calculations and Gain Scheduling

Configure input and output calculations to modify controller data
Configure gain scheduling to modify model gains on the fly
Configure and manage model switching
Workshop: Fractionator Controller - Configure custom built controller calculations

External Targets

Identify and explain the application of External Targets:
External Target Definitions
RTO and IRV Style External Targets
External Target Attributes

Subcontrollers

Identify and explain subcontroller concepts
Discuss MV and CV memberships in Subcontrollers
Subcontrollers and shedding
Introduction to Composites

Ramp Variable Techniques

Learn how to deal with process ramp variables by using one of the following types:
Balanced Ramps
Ramps with allowed Imbalance
Program Imbalance Ramps
Pseudo-ramps
Discuss the effects of the ramp horizon on ramp calculation
Workshop: DemoCol Controller - Observe the effects of changing tuning parameters on ramp behavior

New Features in Aspen APC Suite

Review the new features available with Aspen DMC3 controllers

Appendix: Controller Variable Validation

Learn how to deal with the Controller's variable validation process:
General Variables
Manipulated and Feedforward Variables
Subcontrollers and Composite
External Targets

Certification Exam

Register for a Class

Date	Class Type	Location	Price	Language
Date(s): 02/3/2025 - 02/7/2025	Type: Public Classroom	Location: C2, Reading International Business Park, Basingstoke Road Reading , United Kingdom RG2 6DT	Price: (USD) 5000.00	Language: English	Register
Date(s): 02/3/2025 - 02/7/2025	Type: Public Virtual	Location: Virtual-EMEA	Price: (USD) 5000.00	Language: English	Register
Date(s): 05/12/2025 - 05/16/2025	Type: Public Virtual	Location: Virtual-EMEA	Price: (USD) 5000.00	Language: English	Register
Date(s): 05/12/2025 - 05/16/2025	Type: Public Classroom	Location: C2, Reading International Business Park, Basingstoke Road Reading , United Kingdom RG2 6DT	Price: (USD) 5000.00	Language: English	Register
Date(s): 08/4/2025 - 08/8/2025	Type: Public Virtual	Location: Virtual-EMEA	Price: (USD) 5000.00	Language: English	Register
Date(s): 08/4/2025 - 08/8/2025	Type: Public Classroom	Location: C2, Reading International Business Park, Basingstoke Road Reading , United Kingdom RG2 6DT	Price: (USD) 5000.00	Language: English	Register
Date(s): 11/3/2025 - 11/7/2025	Type: Public Classroom	Location: C2, Reading International Business Park, Basingstoke Road Reading , United Kingdom RG2 6DT	Price: (USD) 5000.00	Language: English	Register

Aspen Technology, Inc. awards Continuing Education Units (CEUs) for training classes conducted by our organization. One CEU is granted for every 10 hours of class participation.

Introduction to Aspen DMCplus for APC Engineers

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Training Details

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