Operational leading indicator (OLI) management using in-memory database

What is claimed is: 1. A computer-implemented method comprising: extracting performance data of a process from a data object of an application to an in-memory database of a computer system, wherein the performance data is extracted to the in-memory database in real time from unmodified source data without preaggregation; storing the performance data in the in-memory database; performing statistical analysis on the performance data to generate a model of at least one operational leading indicator (OLI) of the process, the model comprising calculation of a ratio without an index artifact, the ratio evaluating a first condition comprising a lock indicator of the data object in the application, and a second condition evaluating a threshold absolute balance of the data object over a defined number of posting periods, wherein the statistical analysis is performed using in-memory computing directly on the performance data stored in the in-memory database without requiring separate computer hardware; storing the model of the OLI in the in-memory database; causing an in-memory database engine in communication with the model to receive inputs for performance values and performance measures of the process; causing the in-memory database engine to process an output of the statistical analysis of the model in order to produce a cost measure; performing, by the computer system, ongoing measurements of operational performance of the process from the output of the statistical analysis of the model; determining, by the computer system, variations in the operational performance of the process in response to the ongoing measurements; and implementing, by the computer system, corrective action based on the variations in the operational performance of the process. 2. A method as in claim 1 wherein the in-memory database engine conducts predictive modeling correlating a measure of process inefficiency with the performance data to predict the cost measure. 3. A method as in claim 2 wherein the in-memory database engine further conducts operational modeling identifying variables affecting the process. 4. A method as in claim 1 further comprising causing the in-memory database engine to perform a what-if simulation based upon a new value for performance factors specified by a user. 5. A method as in claim 1 further comprising causing the in-memory database engine to merge the model of the OLI with a model of a related OLI in order to create a composite index. 6. A method as in claim 1 wherein the statistical analysis comprises linear regression. 7. A non-transitory computer readable storage medium embodying a computer program for performing a method, said method comprising: extracting performance data of a process from a data object of an application to an in-memory database of a computer system, wherein the performance data is extracted to the in-memory database in real time from unmodified source data without preaggregation; storing the performance data in the in-memory database; performing statistical analysis on the performance data to generate a model of at least one operational leading indicator (OLI) of the process, the model comprising calculation of a ratio without an index artifact, the ratio evaluating a first condition comprising a lock indicator of the data object in the application, and a second condition evaluating a threshold absolute balance of the data object over a defined number of posting periods, wherein the statistical analysis is performed using in-memory computing directly on the performance data stored in the in-memory database without requiring separate computer hardware; storing the model of the OLI in the in-memory database; causing an in-memory database engine in communication with the model to receive inputs for performance values and performance measures of the process; causing the in-memory database engine to process an output of the statistical analysis of the model in order to produce a cost measure; performing, by the computer system, ongoing measurements of operational performance of the process from the output of the statistical analysis of the model; determining, by the computer system, variations in the operational performance of the process in response to the ongoing measurements; and implementing, by the computer system, corrective action based on the variations in the operational performance of the process. 8. A non-transitory computer readable storage medium as in claim 7 wherein the in-memory database engine conducts predictive modeling correlating a measure of process inefficiency with the performance data to predict the cost measure. 9. A non-transitory computer readable storage medium as in claim 8 wherein the in-memory database engine further conducts operational modeling identifying variables affecting the process. 10. A non-transitory computer readable storage medium as in claim 7 wherein the method further comprises causing the in-memory database engine to perform a what-if simulation based upon a new value for performance factors specified by a user. 11. A non-transitory computer readable storage medium as in claim 7 wherein the method further comprises causing the in-memory database engine to merge the model of the OLI with a model of a related OLI in order to create a composite index. 12. A non-transitory computer readable storage medium as in claim 7 wherein the statistical analysis comprises linear regression. 13. A computer system comprising: one or more processors; a software program, executable on said computer system, the software program configured to: extract performance data of a process from a data object of an application to an in-memory database of the computer system, wherein the performance data is extracted to the in-memory database in real time from unmodified source data without preaggregation; store the performance data in the in-memory database; perform statistical analysis on the performance data to generate a model of at least one operational leading indicator (OLI) of the process, the model comprising calculation of a ratio without an index artifact, the ratio evaluating a first condition comprising a lock indicator of the data object in the application, and a second condition evaluating a threshold absolute balance of the data object over a defined number of posting periods, wherein the statistical analysis is performed using in-memory computing directly on the performance data stored in the in-memory database without requiring separate computer hardware; store the model of the OLI in the in-memory database; cause an in-memory database engine in communication with the model to receive inputs for performance values and performance measures of the process; cause the in-memory database engine to process an output of the statistical analysis of the model in order to produce a cost measure; performing ongoing measurements of operational performance of the process from the output of the statistical analysis of the model; determining variations in the operational performance of the process in response to the ongoing measurements; and implementing corrective action based on the variations in the operational performance of the process. 14. A computer system as in claim 13 wherein the in-memory database engine conducts predictive modeling correlating a measure of process inefficiency with the performance data to predict the cost measure. 15. A computer system as in claim 14 wherein the in-memory database engine is caused to further conduct operational modeling identifying variables affecting the process. 16. A comp