Data validation and reconciliation
Industrial process data validation and reconciliation, or more briefly, data validation and reconciliation , is a technology that uses process information and mathematical methods in order to automatically ensure data validation and reconciliation by correcting measurements in industrial processes. The use of DVR allows for extracting accurate and reliable information about the state of industry processes from raw measurement data and produces a single consistent set of data representing the most likely process operation.
Models, data and measurement errors
Industrial processes, for example chemical or thermodynamic processes in chemical plants, refineries, oil or gas production sites, or power plants, are often represented by two fundamental means:- Models that express the general structure of the processes,
- Data that reflects the state of the processes at a given point in time.
Error types
Data originates typically from measurements taken at different places throughout the industrial site, for example temperature, pressure, volumetric flow rate measurements etc. To understand the basic principles of DVR, it is important to first recognize that plant measurements are never 100% correct, i.e. raw measurement is not a solution of the nonlinear system. When using measurements without correction to generate plant balances, it is common to have incoherencies. Measurement errors can be categorized into two basic types:- random errors due to intrinsic sensor accuracy and
- systematic errors due to sensor calibration or faulty data transmission.
Other sources of errors when calculating plant balances include process faults such as leaks, unmodeled heat losses, incorrect physical properties or other physical parameters used in equations, and incorrect structure such as unmodeled bypass lines. Other errors include unmodeled plant dynamics such as holdup changes, and other instabilities in plant operations that violate steady state models. Additional dynamic errors arise when measurements and samples are not taken at the same time, especially lab analyses.
The normal practice of using time averages for the data input partly reduces the dynamic problems. However, that does not completely resolve timing inconsistencies for infrequently-sampled data like lab analyses.
This use of average values, like a moving average, acts as a low-pass filter, so high frequency noise is mostly eliminated. The result is that, in practice, data reconciliation is mainly making adjustments to correct systematic errors like biases.
Necessity of removing measurement errors
ISA-95 is the international standard for the integration of enterprise and control systems It asserts that:Data reconciliation is a serious issue for enterprise-control integration. The data have to be valid to be useful for the enterprise system. The data must often be determined from physical measurements that have associated error factors. This must usually be converted into exact values for the enterprise system. This conversion may require manual, or intelligent reconciliation of the converted values .
Systems must be set up to ensure that accurate data are sent to production and from production. Inadvertent operator or clerical errors may result in too much production, too little production, the wrong production, incorrect inventory, or missing inventory.
History
DVR has become more and more important due to industrial processes that are becoming more and more complex. DVR started in the early 1960s with applications aiming at closing material balances in production processes where raw measurements were available for all variables. At the same time the problem of gross error identification and elimination has been presented. In the late 1960s and 1970s unmeasured variables were taken into account in the data reconciliation process., DVR also became more mature by considering general nonlinear equation systems coming from thermodynamic models.,, Quasi steady state dynamics for filtering and simultaneous parameter estimation over time were introduced in 1977 by Stanley and Mah. Dynamic DVR was formulated as a nonlinear optimization problem by Liebman et al. in 1992.
Data reconciliation
Data reconciliation is a technique that targets at correcting measurement errors that are due to measurement noise, i.e. random errors. From a statistical point of view the main assumption is that no systematic errors exist in the set of measurements, since they may bias the reconciliation results and reduce the robustness of the reconciliation.Given measurements, data reconciliation can mathematically be expressed as an optimization problem of the following form:
where
is the reconciled value of the -th measurement, is the measured value of the -th measurement, is the -th unmeasured variable, and is the standard deviation of the -th measurement,
are the process equality constraints and
are the bounds on the measured and unmeasured variables.
The term is called the penalty of measurement i. The objective function is the sum of the penalties, which will be denoted in the following by.
In other words, one wants to minimize the overall correction that is needed in order to satisfy the system constraints. Additionally, each least squares term is weighted by the standard deviation of the corresponding measurement. The standard deviation is related to the accuracy of the measurement. For example, at a 95% confidence level, the standard deviation is about half the accuracy.
Redundancy
Data reconciliation relies strongly on the concept of redundancy to correct the measurements as little as possible in order to satisfy the process constraints. Here, redundancy is defined differently from redundancy in information theory. Instead, redundancy arises from combining sensor data with the model, sometimes more specifically called "spatial redundancy", "analytical redundancy", or "topological redundancy".Redundancy can be due to sensor redundancy, where sensors are duplicated in order to have more than one measurement of the same quantity. Redundancy also arises when a single variable can be estimated in several independent ways from separate sets of measurements at a given time or time averaging period, using the algebraic constraints.
Redundancy is linked to the concept of observability. A variable is observable if the models and sensor measurements can be used to uniquely determine its value. A sensor is redundant if its removal causes no loss of observability. Rigorous definitions of observability, calculability, and redundancy, along with criteria for determining it, were established by Stanley and Mah, for these cases with set constraints such as algebraic equations and inequalities. Next, we illustrate some special cases:
Topological redundancy is intimately linked with the degrees of freedom of a mathematical system, i.e. the minimum number of pieces of information that are required in order to calculate all of the system variables. For instance, in the example above the flow conservation requires that. One needs to know the value of two of the 3 variables in order to calculate the third one. The degrees of freedom for the model in that case is equal to 2. At least 2 measurements are needed to estimate all the variables, and 3 would be needed for redundancy.
When speaking about topological redundancy we have to distinguish between measured and unmeasured variables. In the following let us denote by the unmeasured variables and the measured variables. Then the system of the process constraints becomes, which is a nonlinear system in and.
If the system is calculable with the measurements given, then the level of topological redundancy is defined as, i.e. the number of additional measurements that are at hand on top of those measurements which are required in order to just calculate the system. Another way of viewing the level of redundancy is to use the definition of, which is the difference between the number of variables and the number of equations. Then one gets
i.e. the redundancy is the difference between the number of equations and the number of unmeasured variables. The level of total redundancy is the sum of sensor redundancy and topological redundancy. We speak of positive redundancy if the system is calculable and the total redundancy is positive. One can see that the level of topological redundancy merely depends on the number of equations and the number of unmeasured variables and not on the number of measured variables.
Simple counts of variables, equations, and measurements are inadequate for many systems, breaking down for several reasons: Portions of a system might have redundancy, while others do not, and some portions might not even be possible to calculate, and Nonlinearities can lead to different conclusions at different operating points. As an example, consider the following system with 4 streams and 2 units.
Example of calculable and non-calculable systems
We incorporate only flow conservation constraints and obtain and. It is possible that the system is not calculable, even though.If we have measurements for and, but not for and, then the system cannot be calculated. On the other hand, if and are known, but not and, then the system can be calculated.
In 1981, observability and redundancy criteria were proven for these sorts of flow networks involving only mass and energy balance constraints. After combining all the plant inputs and outputs into an "environment node", loss of observability corresponds to cycles of unmeasured streams. That is seen in the second case above, where streams a and b are in a cycle of unmeasured streams. Redundancy classification follows, by testing for a path of unmeasured streams, since that would lead to an unmeasured cycle if the measurement was removed. Measurements c and d are redundant in the second case above, even though part of the system is unobservable.
Benefits
Redundancy can be used as a source of information to cross-check and correct the measurements and increase their accuracy and precision: on the one hand they reconciled Further, the data reconciliation problem presented above also includes unmeasured variables. Based on information redundancy, estimates for these unmeasured variables can be calculated along with their accuracies. In industrial processes these unmeasured variables that data reconciliation provides are referred to as soft sensors or virtual sensors, where hardware sensors are not installed.Data validation
Data validation denotes all validation and verification actions before and after the reconciliation step.Data filtering
Data filtering denotes the process of treating measured data such that the values become meaningful and lie within the range of expected values. Data filtering is necessary before the reconciliation process in order to increase robustness of the reconciliation step. There are several ways of data filtering, for example taking the average of several measured values over a well-defined time period.Result validation
Result validation is the set of validation or verification actions taken after the reconciliation process and it takes into account measured and unmeasured variables as well as reconciled values. Result validation covers, but is not limited to, penalty analysis for determining the reliability of the reconciliation, or bound checks to ensure that the reconciled values lie in a certain range, e.g. the temperature has to be within some reasonable bounds.Gross error detection
Result validation may include statistical tests to validate the reliability of the reconciled values, by checking whether gross errors exist in the set of measured values. These tests can be for example- the chi square test
- the individual test.
The individual test compares each penalty term in the objective function with the critical values of the normal distribution. If the -th penalty term is outside the 95% confidence interval of the normal distribution, then there is reason to believe that this measurement has a gross error.
Advanced data validation and reconciliation
Advanced data validation and reconciliation is an integrated approach of combining data reconciliation and data validation techniques, which is characterized by- complex models incorporating besides mass balances also thermodynamics, momentum balances, equilibria constraints, hydrodynamics etc.
- gross error remediation techniques to ensure meaningfulness of the reconciled values,
- robust algorithms for solving the reconciliation problem.
Thermodynamic models
Gross error remediation
Gross errors are measurement systematic errors that may bias the reconciliation results. Therefore, it is important to identify and eliminate these gross errors from the reconciliation process. After the reconciliation statistical tests can be applied that indicate whether or not a gross error does exist somewhere in the set of measurements. These techniques of gross error remediation are based on two concepts:- gross error elimination
- gross error relaxation.
Gross error relaxation targets at relaxing the estimate for the uncertainty of suspicious measurements so that the reconciled value is in the 95% confidence interval. Relaxation typically finds application when it is not possible to determine which measurement around one unit is responsible for the gross error. Then measurement uncertainties of the measurements involved are increased.
It is important to note that the remediation of gross errors reduces the quality of the reconciliation, either the redundancy decreases or the uncertainty of the measured data increases. Therefore, it can only be applied when the initial level of redundancy is high enough to ensure that the data reconciliation can still be done.
Workflow
Advanced DVR solutions offer an integration of the techniques mentioned above:- data acquisition from data historian, data base or manual inputs
- data validation and filtering of raw measurements
- data reconciliation of filtered measurements
- result verification
- * range check
- * gross error remediation
- result storage
Applications
DVR finds application mainly in industry sectors where either measurements are not accurate or even non-existing, like for example in the upstream sector where flow meters are difficult or expensive to position ; or where accurate data is of high importance, for example for security reasons in nuclear power plants. Another field of application is performance and process monitoring in oil refining or in the chemical industry.As DVR enables to calculate estimates even for unmeasured variables in a reliable way, the German Engineering Society has accepted the technology of DVR as a means to replace expensive sensors in the nuclear power industry.