Decision Guidance Approach to Power Network
Analysis and Optimization
Roberto Levy
1
, Alexander Brodsky
1
and Juan Luo
2
1
Computer Science Department, George Mason University, Va, 22030, Fairfax, U.S.A.
2
Information Technology Unit, George Mason University, Va, 22030, Fairfax, U.S.A.
Keywords: Decision Support, Decision Guidance, Optimization, HRES, Electric Power Network.
Abstract: This paper focuses on developing an approach and technology for actionable recommendations on the
operation of electric power network components. The overall direction of this research is to model the major
components of a Hybrid Renewable Energy System (HRES), including power generation,
transmission/distribution, power storage, energy markets, and end customer demand. First, we propose a
conceptual diagram notation for power network topology, to allow the representation of an arbitrary complex
power system. Second, we develop a formal mathematical model that describes the HRES optimization
framework, consisting of the different network components, their respective costs, and associated constraints.
Third, we implement the HRES optimization problem solution through a mixed-integer linear programming
(MILP) model by leveraging IBM Optimization Programming Language (OPL) CPLEX Studio. Lastly, we
demonstrate the model through an example of a simulated network, showing the ability to support sensitivity
/ what-if analysis, to determine the behavior of the network under different configurations.
1 INTRODUCTION
We have seen in recent years several trends, which
are significantly transforming the existing
mechanisms for supplying energy to satisfy
electricity demand. At the forefront, environmental
concerns are driving a surge in motivation to integrate
renewable energy sources into the power grid.
Political factors exacerbate this trend, as there is a
significant push for reducing dependency on
imported fossil fuels. Economic aspects take into
consideration the financial viability of operating
those solutions, as well as the need to maintain a
reliable source of supply.
This last factor represents a potential problem for
the effective deployment of some of the most
promising renewable sources, such as wind and solar,
stemming from the uncertain nature of their
generation, which could drive volatility of the energy
supply.
Several complementary elements come into place
to address these issues. The establishment of smart
grids, which expand the more traditional power grids
by using two-way flows of electricity and information
to create an automated and distributed advanced
energy delivery network. Figure 1 (U.S. Energy
Information Administration, 2014), depicts a typical
network configuration for a power grid. As a
specialization of these smart grids, we see the
development of Hybrid Renewable Energy Systems
(HRES), or Integrated Renewable Energy Systems
(IRES), both of which denote an elaborated energy
grid that relies on multiple sources - in general,
renewable ones such as solar, wind, and hydro,
combined with traditional sources such as diesel, and
the placement of storage technology at key locations
on the grid, to establish a reliable, cleaner and stable
flow of supply.
A key problem facing decision makers is to find
the most efficient way to operate such grids, which
are becoming increasingly more complex, including
different types of generation facilities, electricity
storage equipment deployed throughout the network,
transmission and distribution facilities, sources of
demand scattered through a region, and markets for
buying/selling energy and/or capacity. The question
of electricity storage is a particularly important one,
involving the options of placing the right storage
technology at key locations to address multiple needs:
balancing power supply to compensate for potential
fuel shortages and the stochastic nature of renewable
sources; deferring costly upgrades of the
transmission/distribution infrastructure by placing
storage technology next to the end consumer location;
Levy, R., Brodsky, A. and Luo, J.
Decision Guidance Approach to Power Network Analysis and Optimization.
In Proceedings of the 18th International Conference on Enterprise Information Systems (ICEIS 2016) - Volume 2, pages 109-117
ISBN: 978-989-758-187-8
Copyright
c
2016 by SCITEPRESS – Science and Technology Publications, Lda. All rights reserved
109
allowing frequency regulation; and creating
opportunity for revenue generation through
secondary markets.
This paper focuses on the problem of determining
the optimal operation of the network in the short term,
taking into account the components of power
generation, storage placement, transmission, external
markets, and consumption. The underlying decisions
relate to the optimal flows and mode of operation of
each component of the smart grid. Most of the current
research in the area exhibits several limitations: it
focuses on more specific aspects of the network, as
opposed to an integrated view; is based on mostly
simulation engines or heuristics, not on mathematical
programming optimization; and much is focused on
micro-grids, rather than largely distributed networks.
Addressing those limitations is exactly the focus
of the present research, proposing and implementing
a decision guidance framework for optimal operation
of power networks with renewable resources and
storage. We propose a conceptual diagram notation
for power network topology, to represent Hybrid
Renewable Energy Systems (HRES). We develop a
formal mathematical model that describes the HRES
optimization framework, consisting of the different
network components, their respective costs, and
associated constraints. We implement the HRES
optimization problem solution through a mixed-
integer linear programming (MILP) model by
leveraging IBM Optimization Programming
Language (OPL) and CPLEX Studio. Lastly, we
demonstrate the model through an example of a
simulated network, showing also the ability to
support sensitivity and what-if analysis to determine
the behavior of the network under different
configurations.
There are several benefits to be achieved by the
development of such a model. First, in a context of
uncertain and probable growing demand, by allowing
the planning and simulation of placement of
components (including storage solutions) in different
key locations on the grid, we can make a realistic
assessment of their best utilization, and consequently,
defer a potentially expensive upgrade of distribution
lines. Second, we can minimize overall costs
associated with regular operations due to a more
efficient combination of power flows and use of
storage. Third, we can profitably leverage existing
energy markets, to sell excess capacity at periods of
low demand. And finally, as a clear trend exists for
transitioning from fossil fuels to renewable sources,
the model can support a realistic analysis of how best
to perform this transition.
Figure 1: Distributed power system with storage
technologies (Source: U.S. Energy Information
Administration).
2 RELATED WORK
A significant body of research has been developed in
the past few years to address the smart grid and the
aspects related to its planning and operations. The
first group of research surveys existing work on the
topic rather than proposing new methods. Fang et al.
(2011) define the smart grid as an enhancement to the
traditional power grid of the 20th century, by
leveraging two-way flows of electricity and
information to create an automated and distributed
advanced energy delivery network. They performed a
survey of a large amount of work, classified into three
major categories: Infrastructure System (i.e. the
technologies underlying the Smart Grid for
generation, information control and
communications); Management System
(management techniques for optimal operation of the
grid); and Protection System (security). Our present
work falls mainly in the second category.
Other surveys (Baños et al., 2011; Erdinc and
Uzunoglu, 2012; Chauhan and Saini, 2014) provide a
comprehensive review of optimization and heuristic
methods applied to individual renewable sources of
energy to achieve optimal sizing of components.
Similarly, Deshmukh and Deshmukh (2008) provide
a review of the mathematical modelling of the
different components of an HRES. The methods
covered include traditional methods such as Linear
Programming (LP), Quadratic Programming (QP),
Mixed Integer-Linear Programming (MILP), as well
as heuristics and meta-heuristics approaches,
including Genetic Algorithms (GA), Particle Swarm
Optimization (PSO), Artificial Neural Networks
(ANN), and others. Although robust results were
ICEIS 2016 - 18th International Conference on Enterprise Information Systems
110
achieved in those areas, the research focuses on
optimizing the size of individual sources, and does
not deal with the energy flows between components
involved in the operations of the combined network.
As many of the optimization models deal with
multi-objective optimization, conventional methods
can be used through unification of the objectives into
one consolidated function, or through a Pareto-
optimal set, in which a set of non-dominated solutions
are selected. Alternatively, less traditional methods
are proposed (Katsigiannis et al., 2010), in which a
Multi-Objective Genetic Algorithm is utilized to
minimize the system long term Cost of Energy (COE)
as well as the amount of emission of CO
2
–
equivalents, using a life-cycle approach that takes
into account emission beyond the production of
energy. This model, however, is designed to address
the optimal combination to be utilized among the
different components, but does not address the design
of a flexible network from an operational perspective,
as we do in our model.
Several models have been developed to explore
other alternative methodologies, with the intent of
deflecting the inherent difficulty of traditional
optimization models. Mahor et al. (2009) provide a
review of multiple papers that attempt to overcome
the problem through the use of Particle Swarm
Optimization (PSO), but those papers focus on the so
called ‘Economic Dispatch’ problem, and on
planning the output of given set of generating units.
For this problem, the network flows did not play a
role. Courtecuisse et al. (2010) propose a
methodology for designing a fuzzy logic based
supervision model for an HRES, based on the
guidance of maximizing the usage of wind power, and
minimizing the use of non-renewable power by
designing a supervisor system that controls the power
generation of each component, and its frequency.
However, they do not attempt to optimize the
functioning of the HRES for cost, environmental
impact, or other objectives.
Much work is focused on the demand side,
ranging from prediction models based on Artificial
Neural networks (Yokoyama et al., 2009; Ekonomou,
2010), to learning consumer behavior through
piecewise regression (Luo et al., 2012; Luo and
Brodsky, 2010), and to mechanisms for Demand Side
Management (DSM) and Demand Regulation (DR) to
counter the constraints on the renewable energy
supply (Moura and de Almeida, 2010). This line of
work complements our solution, in terms of load and
consumption projections, but it does not address our
main area of focus.
Other research focuses on simulating the HRES
model, and on developing optimization strategy to
minimize Net Present Cost (investment costs plus the
discounted present value of all future costs) or the
‘Levelized’ Cost of Energy (total cost of the entire
hybrid system divided by the energy supplied by the
same) (Bernal-Agustin and Dufo-Lopez, 2009).
Although the concept is useful in solving complex
and non-linearized problems, it focuses on stand-
alone hybrid system, not on distributed networks.
Several papers focus on optimization of hybrid
models through Linear Programming approaches
(Cormio et al., 2003), where the model describes the
energy system as a network of flows, by combining
the use of multiple sources (renewable and non-
renewable) of energy services, through a given
planning horizon. The objective function to be
minimized encompasses all fixed and variable costs
(investment and operations), subject to a series of
constraints related to demand, sources, environmental
impacts, etc. The model builds on a comprehensive
modelling of the different elements/components for
generation and consumption, however, it does not
support a modular approach for adding components
located in different parts of the network, with
considerations of distribution flows among possibly
segregated regions.
In the realm of software solution packages, many
comprehensive models were also developed, one of
the best known being HOMER (Lambert et al., 2006),
which provides a robust framework for planning and
simulating an HRES model for a micro-grid, and
driving the identification of the optimal model
through the simulation of discrete number of
scenarios. A good number of packages were
developed in the same vein. HOMER (as well as other
similar packages), offers a user-friendly framework
that allows the flexibility to incorporate the elements
as required, by establishing options for each
component, amount, and sizing, together with the
determination of patterns for the grid load, and
external factors such as wind, sunlight, etc. that affect
the behavior of the components. Their framework,
however, does not address the problem which is the
focus of our research in two respects: it is based on a
simulation approach as opposed to relying on true
optimization techniques, and it solves the problem for
micro-grid planning but does not address a larger
energy distribution network.
Decision Guidance Approach to Power Network Analysis and Optimization
111
3 TOPOLOGY
REPRESENTATION FOR
POWER NETWORKS
Based on the power network depiction in Figure 1, we
generate a topology diagram (Figure 2), which maps
every physical facility in the picture to a
corresponding component in the diagram below,
Orange circles represent generators, blue circles
represent aggregators, yellow circles represent
market, green circles represent storage (for the
purpose of this exercise, we don’t differentiate
between different storage technologies, purple circles
represent transmissions, lines represent power flows,
small ovals represent the power flow identifiers, and
red rectangles represent demand (both residential and
commercial).
Figure 2: Topology Diagram.
This diagram can serve as the basis for establishing
the formal model in the next section, as well as the
case study subsequently, as it provides a modular
view for the components to be assembled in distinct
forms to reflect different network configurations.
The topology diagram can be used for two
interrelated decision problems:
1. Operational (short term) – for every hourly
interval, determine the optimal power flows
across multiple components to satisfy projected
demand during a given time horizon, while
optimizing an objective function (e.g. cost
optimization, emissions, or a combination of
factors). A decision to be made at the beginning
of each hourly interval, as a rolling time horizon.
2. Planning/Investment (mid to long term) – based
on expected demand growth, decide on preferred
investments on network improvements. This
problem normally involves decision on policy,
when evaluating larger scales networks.
This paper focuses on problem 1 – although it can
support the analysis on problem 2, by allowing what-
if analysis on the operations under each option being
evaluated.
In the next section, we will introduce a formal
description of the model, addressing the key
considerations for each component, as well as the
main variables involved.
4 FORMAL MODEL
4.1 HRES Optimization Framework
We define an optimization framework as a tuple:
HRES:
,,,,,,,,,,,
Where:
T =
1,2,3 …
is the Time Horizon with
fixed intervals 1, 2,…, N (each with duration
IntervalLength)
F is the set of flow ids between the
components of the network
A is the set of aggregator ids
AIF: →2
is an Aggregator Input Flow
function that, for each aggregator ∈
,gives a set of its input flows AIF(a)
AOF: →2
is an Aggregator Output Flow
function that, for each aggregator ∈
,gives a set of its output flows AOF(a)
CMP is the set of component ids, including
generators, transmission/distribution,
batteries, demand sources
CIF: → ∪ , where Λ∉,is a
function that, for every component ,
gives:
1
∈
OR
2
Λ
COF: → ∪ , where Λ∉,is a
function that, for every component ,
gives:
1
∈
OR
2
Λ
DS = (D, dF), is the Demand Structure tuple,
where:
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D
⊆
CMP is a set of demand source IDs;
We require that demand source IDs do not
have output flows, i.e.
∀ ∈
dF: →
is the demand function
that, for each demand source d and time
interval t, gives the predicted demand
dF[d,t] in kw.
GS = (G, fPr, gCap, gEff) is the Generators
Structure tuple, where:
o G
⊆
CMP is the set of generator ids;
we require that generators do not have
input flows, i.e.
o
∀ ∈
o : →
is the price function
that for each generator g and time
interval t, gives the expected fuel price
fPr[g,t] in $/Btu
o : →
is a function that gives
for each generator g, the maximal
capacity of generation gCap(g) in kw
o : →
is the function that gives
for each generator g, the efficiency
gEff(g) in Btu/kw.
, , ,
/
, :
o TD
⊆
CMP is the set of
Transmission/ ids
o : → 0,1 is the Loss Ratio of
each Transmission/
id
o TMC: →
is the annual
maintenance cost for each
Transmission/ id
o : T→
is the maximal
capacity of transmission in kw for
each Transmission/
id
BS = (B, NBC, BLC, BMC, bcF, BIE, M, bmP,
ppC) is the Battery Structure tuple, where:
o B
⊆
CMP is the set of Battery ids
o NBC: →
is the new battery
cost (for replacing each battery id)
o BLC: →
is the Battery
Lifecycle Parameter, for each
battery id
o BMC:B →
is the annual
maintenance cost for each Battery
id
o bcF: →
is the battery
capacity function that for each
battery b and time interval t, gives
the expected energy storage
capacity bcF(b,t) in kwh
o BIE: B →
is the battery initial
energy level at t = 0
o M is set of market ids being served
by batteries
o bmP: BM → , are all
battery-market pairs, for ∀ ∈
and ∀ ∈
o ppC: B →
is the price that
each market is willing to pay for
committed capacity (in $/kw)
4.2 HRES Optimization Problem
The formal HRES Optimization is stated as:
Min
,,,,,
(1)
Subject to Ca, Cg, Ctd, Cd, Cb
Where the decision variables, objective and
constraints are given below:
Decision Variables:
kw is the matrix of elements kw[f,t], where for
every flow f ∊ F and every time interval t ,
kw[f,t] gives the the amount of kilowatts
transferred between two components
bE is the amount of energy stored in a battery at
a time interval t
cFL is the Boolean value (charge flag) that
indicates if a battery is being charged at a time
interval t
dFL is the Boolean value (discharge flag) that
indicates if a battery is being discharged at a time
interval t.
c2mFL is the Boolean value (commit to market
flag) that indicates if a battery’s capacity is
committed to a market at a time interval t
cC is the committed capacity of a battery to a
market at a time interval t
Objective Function:
(2)
where:
RevAdjCost is the overall cost through the time
horizon reduced by market revenue
gC is the cost associated with operating the
power generators during the time horizon (see
section 4.4)
tC is cost of maintaining the Transmission/
Distribution stations during the time horizon (see
section 4.5)
Decision Guidance Approach to Power Network Analysis and Optimization
113
bC is the cost of operating the batteries, as well
as the associated battery depreciation cost, based
on usage through the time horizon (see section
4.7.1)
mR is the revenue associated with committing
batteries to market throughout the time horizon
(see section 4.7.2)
Constraints:
Ca = Aggregators’ constraints (see section 4.3)
Cg = Generators’ constraints (see section 4.4)
Ctd = Transmission/Distribution constraints (see
section 4.5)
Cd = Demand constraints (see section 4.6)
Cb = Batteries’ constraints (see section 4.7.3)
4.3 Aggregators
Power Aggregators consolidate power flows
originated from m different sources, and redistribute
the same flows into n different destinations. We
assume no operational costs to be incurred with
power aggregators.
The main constraint for each Aggregator is given by:
Ca:
∑
,
∑
,
∈
∀
,
(3)
4.4 Generators
We assume only output flows from the Power
Generators (in the simplified case of only
combustible fuel generators). The cost of operating
each power generator is given by the fuel cost
(Dollars per BTU), the generator efficiency (BTU per
kWh), and the amount of output flow during the given
time interval:
GenCost[,t] = fPR[,t] * gEff [] * kw[f,
t] * IntervalLength
( ∀, ,
(4)
Total operating cost for all generators across the
whole time horizon is given by the sum of GenCost
across Generator Ids and time intervals t, i.e.
gC =
∑
,
,
(5)
he only constraint for the output flow is given by
the generator’s maximal capacity:
Cg: kw[f,t] gCap[]
∀, ,
(6)
4.5 Transmission/Distribution
The total cost associated with
transmission/distribution is given by the sum of the
known maintenance costs for each distribution station
through the time horizon, i.e.
tC =
∑
(7)
A fixed loss ratio is assumed to be known for each
transmission/distribution station. Therefore, it carries
a constraint of a given relationship between output
and input flows based on the loss ratio:
Ca
1
: kw [f
1
, t] = (1.0 - LR[]) * kw[f
2
,t]
(∀ , ,
1
,
2
(8)
A second constraint is given by the maximal
transmission capacity for the station:
Ca
2:
kw [f,t] tCap[]
(∀ , ,
(9)
4.6 Demand
Given our assumption that all end demand is satisfied,
and only input flows of electric power are applicable,
the main constraint is that the sum of input flows
equals total demand for any end demand point for any
time interval t:
Cd: kw[f,t] = dF[,t]
(∀,,
(10)
For the same reason, revenue from end demand is
not considered in the cost / Revenue optimization (as
it is unchanged for a given demand load).
4.7 Energy Storage / Batteries
4.7.1 Batteries Cost
Cost of operating each battery for any time interval is
given by adding the maintenance cost for the battery,
and its depreciation cost. The depreciation is given by
the cost of battery replacement (NBC), the
cumulative charge and discharge at the end of the
period (cCD) and a known battery lifecycle parameter
(BLC):
bDep[] =
∗ 1
(∀ ,
(11)
The accumulated amount (absolute value) that
charges and discharges through a battery at the end of
each time interval (t+1), is given by:
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cCD[,t+1] = cCD[,t] + (kw[f1,t] + kw[f2,t]) *
IntervalLength
(∀, ,
1
,
2
(12)
where
cCD[][0] = 0 (13)
For the overall Battery Costs:
batCost[] = BMC[] + bDep[] (14)
bC =
∑
∈
(15)
4.7.2 Batteries/ Market Revenue
If a battery is committed to a market for a given time
interval t, additional revenue is generated, given by
the price per capacity for that market and the
committed capacity for the time interval (cC):
ActualMarketRev [, ][t] =
ppc[][t] * cC[][t]
(16)
In this model, for sake of simplicity, the capacity
is treated as constant over the time horizon. Note that
during the time intervals where the battery is
committed to a market, the net flow of energy is zero,
i.e. the energy at the end of the period is equal to that
at the beginning of the same period.
The total market revenue (mR) is given by:
mR =
∑
,
(17)
4.7.3 Batteries/ Market Constraints
At any time interval, as the following battery states
are mutually exclusive:
Charged – only input flows going into the
battery.
Discharged – only output flows going to
subsequent components in the network.
Committed to a market (i.e. using existing
unused capacity at any time interval to sell it to
an external market and provide revenue).
Additionally, any battery can be committed to no
more than one market at any given time interval.
This translates into the following constraints,
(∀, , 1
,2
:
Bc1: cFL[][t] + dFL[][t] +
∑
2,
1
(18)
Bc2: cFL[][t] = 1 iff kw[f1,])> 0
(0 otherwise)
(19)
Bc3: dFL[][t] = 1 iff kw[f2,] > 0
(0 otherwise)
(20)
Regarding the amount of energy stored in the
battery at any point in time, it starts with a given
amount, ends the time horizon with the same amount,
and oscillates throughout the time horizon based on
charges and discharges of the battery:
Bc4: bE[][1] = bE[
][ 1 ] = BIE[] (21)
bE[][1] = bE[][ ] + kw[f1,] – kw[f2,])
* IntervalLength
(22)
5 IMPLEMENTATION AS MILP
AND CASE STUDY
A simple version of this model was developed using
IBM OPL CPLEX Studio.
We proposed different scenarios to provide
insights into the model, and to correspond to the
intuition of what to expect from its behavior for
different combinations of components ads their
characteristics. We also followed a given sequence of
key steps that constitute the methodology: First, we
depict each scenario as the topological representation,
as described in section 3. Next, we capture each of the
component characteristics into the variables defined
by the HRES optimization framework. Lastly, we
implement the MILP problem solution, by translating
these variables into IBM OPL CPLEX Studio, and
running the solver, to derive the solutions.
We examined scenarios in which the different
parameters combinations drive distinct decision
variables for the time horizon. As explained in prior
section, we are examining a 24 hour time horizon,
with a time unit of one hour. For each hourly interval,
in essence, we are determining what would be the
optimal value for power flows, battery states,
commitments and costs, for the full 24-hour time
frame. On real life utilization scenario, two possible
operation modes could be considered: in the first, a
planning engine would run based on the expected
demand for the upcoming day, and after execution,
the planning engine plans the subsequent day
operation; another option, would be to re-evaluate
dynamically the planning within a rolling time
horizon, as every hour we could look at actual values,
as well as adjustments on demand for upcoming 24
hours.
With these insights in mind, we proceeded to scale
up the model, to reflect the topology depicted in
Figure 2, and built (again recurring to synthetic data),
to create the four scenarios depicted below.
Scenario 1: Generation and transmission
capacity can satisfy the demand.
Decision Guidance Approach to Power Network Analysis and Optimization
115
Model recommendation: not using batteries
in operation, and always committing them to
market.
Scenario 2: For some hours in the time horizon,
the fuel cost is very high.
Model recommendation: discharging
batteries at that time.
Scenario 3: The generators capacity cannot
satisfy some peak demand (for some hours of
operation).
Model recommendation: using batteries for
these periods.
Scenario 4: The transmission capacity is limited,
so that it is not sufficient during some hours of
peak demand.
Model recommendation: using the batteries
downstream (at the distribution areas), to
offset lack of power from upstream.
6 CONCLUSIONS AND FUTURE
DIRECTIONS
In this work, we demonstrated an approach for
optimizing the operations of components of an
electric power network, including power generation,
transmission/distribution, power storage, energy
markets, and end customer demand (residential and
commercial). A prototype was developed using IBM
OPL CPLEX Studio, to make recommendations for
operating the network, while minimizing revenue-
adjusted overall costs for a given time horizon. A
simple topology was created, and different scenarios
were examined to assess the basic behavior of the
model, in common situations, based on realistic
synthetic data. The initial results demonstrate the
validity of the approach, and provide some promising
directions for future development, including
operations optimization, investment planning /
policy, and the technology aspects of the solution.
Regarding operations optimization, the model can
be refined in several ways: first, by introducing
energy generation through wind and solar power, as
alternate source to the fuel based generators; second,
by incorporating stochasticity in demand (and
possibly supply too, especially with renewable
sources); Third, by introducing real data.
In the realm of long term planning, the framework
should be expanded, to include infrastructure/ capital
investment recommendations to achieve long term
goals. This process would possibly involve multiple
stakeholders / decision-makers, in the public and
private sectors, which could also drive policy
decisions that address multiple goals (including
environmental impact, regional employment, system
reliability, etc.). The model would evaluate the
effects of different policies (e.g. tax incentives,
emissions regulations), as well as the prioritization of
investment in network assets (such as new batteries,
new distribution lines, etc.).
Finally, from a technology perspective, we could
develop more flexible tools, to allow a more intuitive
and reusable model, as well as incorporating other
features such as learning and prediction mechanisms.
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