GitHub - kLabUM/LIFT: Data and Scripts for LIFT challenge

LIFT Challenge 2018: Open-Storm Detroit Dynamics

Team Members

Wendy Barrot, Program Director R&D, GLWA
Christopher Nastally, Manager, GLWA
Branko Kerkez, Assistant Professor, University of Michigan
Sara Troutman, Ph.D. Student, University of Michigan
Abhiram Mullapudi, Ph.D. Student, University of Michigan
Gregory Ewing, Research Scientist, University of Michigan

In a collaboration between the GLWA (Great Lakes Water Authority) and Real-Time Water Systems Lab at the University of Michigan, we investigate the application of dynamic control to existing infrastructure in real-time to:

Maximize current storage utilization
Reduce combined sewer overflows
Equalize flow to the water resources recovery facility

We aim to deliver a web-based decision support dashboard to be used by operators of the sewer network during wet-weather events (see below). The tool is informed by control algorithms developed through the LIFT Challenge.

Within this repository are functions that execute the control algorithms used to inform the decision support tool. While we do not share the underlying GLWA system model, those interested will be able to apply the control functions to their own system. The underlying model is an EPA SWMM input file; system states and control actions for system assets (e.g., gate positions, pump target settings) are accessed via PySWMM, a Python language SWMM wrapper.

The control algorithm employed here is Market-Based Control in which decisions are made in a virtual marketplace where a commodity is bought and sold by system agents. In this case, the commodity is volumetric capacity within the sewer system, the buyers of this commodity are upstream storage agents (e.g., pump stations, storage basins, inflatable storage dams), and the sellers are downstream points within the sewer network, more specifically the water resources recovery facility. The downstream point has an operator-defined setpoint to achieve; the downstream capacity is determined as the current volume above or below this setpoint. Price of the commodity fluctuates through time and is based on the current state of the system: how much capacity is available and how greatly it is demanded by upstream agents. Water is moved throughout the system via ''purchases'' of capacity by upstream agents, which dictate how much stored water each upstream agent can release to the downstream agents. Because the system considered here is so large and spatially distributed, we divide the system into sub-markets, each with its own price of capacity, one seller/downstream agent, and potentially several buyers/upstream agents.

Each buyer/upstream agent has a particular wealth with which to ''purchase'' capacity which is based on its current volume normalized to its maximum volume capacity; thus, if a storage agent is close to using all of its available volume, it poses more wealth to ''purchase'' more capacity from downstream, that is release more water to avoid flooding locally. The wealth for upstream agent is computed via

where is a weighting parameter describing priority toward mitigating local upstream flooding, is the normalized volume of upstream agent .

The sum of wealth within each sub-market is computed via

where is a binary matrix denoting the sub-market that each upstream agent belongs to.

Each seller/downstream agent determines the cost it places on the commodity based on its current volume about the desired setpoint. The cost of downstream agent is computed as

where is the normalized volume of downstream agent , is the operator-defined normalized volumetric setpoint of agent , and is a weighting parameter describing priority toward achieving the setpoint.

The price of volumetric capacity within sub-market is computed via

where is the number of buyers/upstream agents in sub-market . It is crucial to note that this results in a pareto optimal distribution of capacity for each sub-market, meaning that any benefit to one agent would result in a detriment of other agents.