NZ600150B - Head-end system for advanced metering infrastructure network - Google Patents
Head-end system for advanced metering infrastructure network Download PDFInfo
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- NZ600150B NZ600150B NZ600150A NZ60015012A NZ600150B NZ 600150 B NZ600150 B NZ 600150B NZ 600150 A NZ600150 A NZ 600150A NZ 60015012 A NZ60015012 A NZ 60015012A NZ 600150 B NZ600150 B NZ 600150B
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- event
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- ami
- command signal
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04Q—SELECTING
- H04Q2209/00—Arrangements in telecontrol or telemetry systems
- H04Q2209/60—Arrangements in telecontrol or telemetry systems for transmitting utility meters data, i.e. transmission of data from the reader of the utility meter
-
- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04Q—SELECTING
- H04Q9/00—Arrangements in telecontrol or telemetry systems for selectively calling a substation from a main station, in which substation desired apparatus is selected for applying a control signal thereto or for obtaining measured values therefrom
Abstract
600150 Disclosed is a head-end system (34) for an advanced metering infrastructure (AMI) network. The system (32) includes a processor (40) and a memory accessible by the processor (40). The processor (40) is configured for receiving event signals from AMI meters (30). The event signals are indicative of events occurring at customer locations. The processor (40) determines whether to transmit a command signal to a corresponding AMI meter in response to receiving an event signal from the corresponding AMI meter (30). The command signal is configured to instruct the corresponding AMI meter (30) to perform at least one task in response to the at least one event. The processor (40) transmits the command signal to the corresponding AMI meter in response to determining to transmit the command signal. tive of events occurring at customer locations. The processor (40) determines whether to transmit a command signal to a corresponding AMI meter in response to receiving an event signal from the corresponding AMI meter (30). The command signal is configured to instruct the corresponding AMI meter (30) to perform at least one task in response to the at least one event. The processor (40) transmits the command signal to the corresponding AMI meter in response to determining to transmit the command signal.
Description
HEAD-END SYSTEM FOR ADVANCED METERING INFRASTRUCTURE NETWORK
This application claims priority from United States Application No.
13/113,674 filed on 23 May 2011, the contents of which are to be taken as incorporated herein
by this reference.
BACKGROUND OF THE INVENTION
The present invention relates generally to an advanced metering
infrastructure (AMI) network, and more particularly, to a head-end system of an AMI network
that includes a processor used to determine whether to transmit a command signal to an AMI
meter.
In order to prevent electricity demand from exceeding power
generation and distribution capabilities during peak energy usage periods, power utility
companies may employ active and/or passive load control techniques to influence electricity
demand. For example, to implement active control of the loads consuming electricity, some
power utilities utilize what is referred to as a “smart grid” or Advanced Metering
Infrastructure (AMI) power network. Using an AMI network, a power utility may
communicate with individual loads within a customer’s premises and selectively reduce power
consumption during peak usage periods. As such, during peak energy usage periods of time, a
power utility may reduce power to low priority loads, while maintaining power to high priority
loads.
In addition to controlling or adjusting the power supplied to
customers, the smart grid may be capable of communicating events, such as errors, alarms,
and other events, from AMI meters to the power utility company, and in turn, the power utility
company may be capable of communicating commands to the AMI meters in response to such
events. In one example, a plurality of AMI meters are connected to a head-end system (HES).
The HES is a system application that operates on the utility network that enables two-way
communication between the AMI meters and the HES. The HES, in turn, is coupled to
external management systems of the power utility company to enable two-way communication
between the HES and the external management systems of the power utility company. Thus,
the HES functions as an interface by relaying event data from the AMI meters to the
appropriate external management system of the power utility company, and by relaying
commands from the external management systems to the appropriate AMI meter.
Because the conventional HES merely functions as a relay interface
that only reports event data to the external management systems and relays commands from
the external management systems to the appropriate AMI meter, the HES does not transmit a
command signal to the AMI meters until the HES receives instructions from the external
management systems. There may be prolonged time lapses between the AMI meter detecting
the event and the AMI receiving a command in response to the event. Such prolonged time
lapses may be due, at least in part, to high network traffic or other problems associated with
expeditiously transmitting signals between the external management systems and the HES.
A reference herein to a patent document or other matter which is given
as prior art is not to be taken as an admission that that document or matter was known or that
the information it contains was part of the common general knowledge as at the priority date
of any of the claims.
BRIEF DESCRIPTION OF THE INVENTION
In one aspect, the present invention provides a head-end system for
use with an advanced metering infrastructure (AMI) network that includes a plurality of AMI
meters at a plurality of customer locations, the head-end system comprising: a processor and a
memory device accessible by said processor, said processor configured for: receiving, at the
head-end system, at least one event signal from each of the AMI meters, wherein the at least
one event signal is indicative of at least one event occurring at a corresponding customer
location; determining, at the head-end system, whether to transmit at least one command
signal to a corresponding AMI meter in response to receiving the at least one event signal
from the corresponding AMI meter, wherein the at least one command signal is configured to
instruct the corresponding AMI meter to perform at least one task in response to the at least
one event; and transmitting, at the head-end system, the at least one command signal to the
corresponding AMI meter in response to determining to transmit the at least one command
signal.
In another aspect, the present invention provides a method of
responding to an event occurring at a customer location using a processor and a memory
device of a head-end system of an advanced metering infrastructure, the method comprising:
receiving at least one event signal from a AMI meter, wherein the at least one event signal is
indicative of at least one event occurring at the customer location; determining whether to
transmit at least one command signal to the AMI meter in response to receiving the at least
one event signal from the AMI meter, wherein the at least one command signal is configured
to instruct the AMI meter to perform at least one task in response to the at least one event; and
transmitting the at least one command signal to the AMI meter in response to determining to
transmit the at least one command signal.
In yet another aspect, the present invention provides an event
communication and response system comprising: a plurality of advanced metering
infrastructure (AMI) meters; a head-end system communicatively coupled to the plurality of
AMI meters, the head-end system comprising a processor and a memory device accessible by
said processor; and a plurality of management systems for managing data from the AMI
meters, the plurality of management systems being communicatively coupled to the head-end
system, wherein the processor of the head-end system is configured for: receiving at least one
event signal from each of the AMI meters, wherein the at least one event signal is indicative of
at least one event occurring at the corresponding AMI meter; determining whether to transmit
at least one command signal to a corresponding AMI meter in response to receiving the at
least one event signal from the corresponding AMI meter, wherein the at least one command
signal is configured to instruct the corresponding AMI meter to perform at least one task in
response to the at least one event; and transmitting the at least one command signal to the
corresponding AMI meter in response to determining to transmit the at least one command
signal.
BRIEF DESCRIPTION OF THE DRAWINGS
Figure 1 is a block diagram of an exemplary energy delivery system.
Figure 2 is a block diagram of an event communication and response
network that may be used with the energy delivery system shown in Figure 1.
Figure 3 is a flowchart of an exemplary method that may be
implemented by a processor of a head-end system used with the event and communication
network shown in Figure 2.
DETAILED DESCRIPTION OF THE INVENTION
Figure 1 is a block diagram of an exemplary energy delivery system
that includes an electric utility 12, an electrical grid 14, and a plurality of customer
locations, such as, for example, a first customer location 16, a second customer location 18,
and a third customer location 20. Customer locations 16, 18, and 20 may include, but are not
limited to, a residence, an office building, an industrial facility, and/or any other building or
location that receives electricity from utility 12. In the exemplary embodiment, electricity is
delivered from electric utility 12 to customer locations 16, 18, and 20 via electrical grid 14. In
the exemplary embodiment, electrical grid 14 includes at least one transmission line 22, an
electrical substation 24, and a plurality of distribution lines 26. Electric utility 12 includes an
electric power generation system 28 that supplies electrical power to electrical grid 14.
Electric power generation system 28 may include a generator driven by, for example, a gas
turbine engine, a hydroelectric turbine, and/or a wind turbine. Alternatively, electric power
generation system 28 may utilize solar panels and/or any other electricity generating device
that allows system 10 to function as described herein. Although the exemplary energy
production and delivery system 10 is an electrical system, in other embodiments the energy
production and delivery system may be a gas system, such as a natural gas system including a
plurality of pipelines and smart gas meters, or another type of energy system.
[0014] Figure 2 is a block diagram of an exemplary event communication and
response system 29 that may be used with energy delivery system 10 (shown in Figure 1).
Figure 3 is a flowchart of an exemplary method that may be implemented by a processor of a
head-end system used with the event and communication network shown in Figure 2. As
illustrated in Figure 2, each customer location 16, 18, and 20 includes an advanced metering
infrastructure (AMI) meter 30. In addition to functioning as a meter that records energy usage,
AMI meters 30 are part an advanced metering infrastructure (AMI) network 32, which is
illustrated schematically in Figure 2. In the exemplary embodiment, AMI network 32 is an
example of a bi-directional communication system that enables electric utility 12 (or any other
energy company) to communicate with AMI meter 30, and vice versa, as explained in more
detail below. AMI meters 30 are communicatively coupled to at least one head-end system
(HES) 34 of AMI network 32, and HES 34 is communicatively coupled to one or more
external management systems 36 of electric utility 12. Examples of management systems 36
include, but are not limited to: Meter Data Management System, Meter Asset Management
System, Distribution Operations System, Customer Information System, Billing System, and
Outage Management System. AMI meters 30 may be communicatively coupled to HES 34 in
any suitable manner that enables operation of AMI network 32 as described herein. HES 34
may be communicatively coupled to one or more management systems 36 in any suitable
manner that enables operation of AMI network 32 as described herein. It should be
understood that AMI network 32 may include more than one HES 34 communicatively
coupled to a different set of AMI meters 30.
Each AMI meter 30 is capable of transmitting one or more event
signals to HES 34. An event signal is indicative of an event occurring at a customer location
16, 18, and 20, or a group of customer locations 16, 18, and 20, associated with a
corresponding AMI meter 30, or a group of AMI meters 30. In non-limiting examples, an
event signal may be indicative of one or more of the following: a meter cover tampering; a
power disconnect switch activated; a circuit breaker tripped; and/or a sag detected. AMI
meters 30 may be capable of detecting an event occurring at customer locations 16, 18, and 20,
or AMI meters 30 may be capable of receiving signals from other devices that detect the event.
Each AMI meter 30 may be capable of transmitting one or more event signals indicative of
one or more of the above-listed events or of other events not listed. AMI meters 30 may
transmit one or more event signals to HES 34 in any suitable way.
[0016] HES 34 includes a processor 40 that receives event signals from AMI
meters 30. The term processor, as used herein, refers to central processing units,
microprocessors, microcontrollers, reduced instruction set circuits (RISC), application specific
integrated circuits (ASIC), logic circuits, and any other circuit or processor capable of
executing the functions described herein. As seen in Figure 3, processor 40 determines
whether to transmit one or more command signals back to a corresponding AMI meter 30
based on the received event signal. A command signal instructs a corresponding AMI meter
to perform a specific task according to the event occurring at the customer location. In one
embodiment, only some event signals have an associated command signal, although each
event signal receivable by HES may have an associated command signal. In addition to
transmitting a command signal, processor 40 may be programmed to transmit one or more
event-notification signals to selected one or more external utility systems and/or transmit one
or more command-notification signals to one or more external utility systems. Each event-
notification signal is indicative of the event signal received by HES 34 from one or more of
the AMI meters 30, and each command-notification signal is indicative of the command signal
transmitted by HES 34 to one or more of the AMI meters 30.
A flowchart, generally indicated at 48, includes an exemplary method
that may be performed by processor 40 of HES 34. In the exemplary method, processor 40
receives 50 an event signal from one of AMI meters 30. Upon receiving 50 the event signal,
processor 40 determines 52, whether there is a command signal associated with the received
event signal. If the received event signal has an associated command signal, then processor
40, transmits 54 a selected command signal, based on the received event signal, to AMI meter
. Processor 40 also transmits 56 and 58, respectively, an event-notification signal and a
command-notification signal to at least one selected management system 36. The event-
notification signal indicates that the head-end system received an event signal from a
corresponding AMI meter 30, and the command-notification signal indicates that the head-end
system transmitted a command signal to corresponding AMI meter 30. If the received event
signal does not have an associated command signal, then processor 40, determines 60 that a
command signal 62 to AMI meter 30 should not be transmitted. Processor 40 may relay 62 a
notification of the event to a selected management system 36.
One example of an HES 34 is shown schematically in Figure 2. In
this embodiment, HES 34 includes a memory device 64 that is communicatively coupled to
processor 40. Memory device 64 may form part of processor 40 or may be external to
processor 40. Memory device 64 stores a computer-readable database associating one or more
selected events with one or more signal-instructions for processor 40. Upon receiving 50 an
event signal, processor 40 is programmed to query 52 database for the event indicated by the
received event signal. If processor 40 locates the event in the database, then the processor
performs 54, 56, and 58 the signal-instructions associated with the event, such as disclosed in
Figure 3. A suitable database may be a lookup table, which can be written in any suitable
computer language, such as XML. An exemplary table is provided below as Table 1.
Table 1
Meter ID Events/Alarms Command External External
Response Back System(s) System(s)
to Meter Notification of Notification of
Events/Alarms Command
Response
Disconnect Deactivate Meter Asset Meter Asset
Meter 1
Switch Disconnect Management Management
Activated Switch System System
Circuit Breaker Activate Outage Outage
Tripped Disconnect Management Management
Switch System System
Sag Detected Activate Outage Outage
Disconnect Management Management
Switch System System
Meter Cover Activate Meter Asset Meter Asset
Tamper Disconnect Management Management
Detection Switch System System
Meter Group Disconnect Deactivate Meter Asset Meter Asset
1 Switch Disconnect Management Management
Activated Switch System System
Meter Cover Activate Meter Asset Meter Asset
Tamper Disconnect Management Management
Detection Switch System System
In the above example, the first column identifies AMI meter 30 and/or
group of AMI meters 30 associated with HES 34. Thus, upon receiving 50 an event signal,
processor 40 queries 52 the database for AMI meter 30 and/or group of AMI meters 30 from
which the event signal was received. Next, processor 40 queries 52 the table to determine
whether the event indicated by the received event signal is listed in the table under
corresponding AMI meter 30 and/or group of AMI meters 30. If the event is listed, then
processor 40 performs 54, 56, 58 the signal-instructions listed in the row associated with the
event. For example, in the above table, the signal-instructions include a command-signal, an
event-notification signal, and a command-notification signal. In particular, as listed in the
second row in the above table, if processor 40 receives an event signal from Meter 1 that is
indicative of a disconnect switch being activated, then processor 40 is instructed to: transmit a
command-signal to AMI meter 30 instructing AMI meter 30 to deactivate the disconnect
switch; transmit an event-notification signal to the Meter Asset Management System of
electric utility 12 indicating that HES 34 received an event signal indicating that a disconnect
switch has been activated; and transmit a command-notification signal to the Meter Asset
Management System of electric utility 12 indicating that HES 34 transmitted a command
signal to AMI meter 30 instructing AMI meter to deactivate disconnect switch.
[0020] If the event is not listed in the table, however, processor may be
configured to relay 62 the event to one or more management systems 36. For example,
processor 40 may query another database or table that includes relay-instructions based on the
event signal received by processor 40.
[0021] In one embodiment, the table may be provided to the electric utility 12
as a template or shell, whereby the electric utility can decide which event signals received by
HES 34 warrant an automated signal-command response from HES 34. Electric utility 12 can
also decide where and when notifications signal are transmitted by HES 34.
[0022] The methods, systems, and apparatus described herein facilitate the
efficient and economical implementation of an HES that is capable of determining whether to
transmit at least one command signal to a corresponding AMI meter in response to receiving at
least one event signal from the corresponding AMI meter and transmitting the at least one
command signal to the corresponding AMI meter in response to determining to transmit the at
least one command signal. In this way, command signals may be transmitted more quickly
and efficiently in response to certain, selected events at the AMI meter, without the need to
wait for the external management systems to transmit the signals. Exemplary embodiments of
methods, systems, and apparatus are described and/or illustrated herein in detail. The
methods, systems, and apparatus are not limited to the specific embodiments described herein,
but rather, components of each system, as well as steps of each method, may be utilized
independently and separately from other components and steps described herein. Each
component, and each method step, can also be used in combination with other components
and/or method steps.
When introducing elements/components/etc. of the methods, systems,
and apparatus described and/or illustrated herein, the articles “a”, “an”, “the”, and “said” are
intended to mean that there are one or more of the element(s)/component(s)/etc. The terms
“comprising”, “including”, and “having” are intended to be inclusive and mean that there may
be additional element(s)/component(s)/etc. other than the listed element(s)/component(s)/etc.
This written description uses examples to disclose the invention,
including the best mode, and also to enable any person skilled in the art to practice the
invention, including making and using any devices or systems and performing any
incorporated methods. The patentable scope of the invention is defined by the claims, and
may include other examples that occur to those skilled in the art. Such other examples are
intended to be within the scope of the claims if they have structural elements that do not differ
from the literal language of the claims, or if they include equivalent structural elements with
insubstantial differences from the literal language of the claims.
Where the terms “comprise”, “comprises”, “comprised” or
“comprising” are used in this specification (including the claims) they are to be interpreted as
specifying the presence of the stated features, integers, steps or components, but not
precluding the presence of one or more other features, integers, steps or components, or group
thereto.
PARTS LIST
Energy delivery system
12 Electric utility
14 Electrical grid
16 First customer location
18 Second customer location
Third customer location
22 Transmission line
24 Electrical substation 24
26 Distribution lines 26
28 Electric power generation system
29 Event communication and response system
AMI meters
32 AMI network
34 Head-end system (HES)
36 Management systems
40 Processor of HES
48 Flowchart
50 Step of receiving event signal from smart energy
meter
52 Step of determining if there is a command signal
associated with the event
54 Step of transmitting associated command signal to
smart energy meter
56 Step of transmitting notification of event to
management system
58 Step of transmitting notification of command signal
to management system
60 Step of not transmitting command signal to smart
meter
62 Step of transmitting notification of event to
management system
64 Memory device of HES
66 Radially outer portion of diaphragm assembly
68 Radially inner portion of diaphragm assembly
Claims (20)
1. A head-end system for use with an advanced metering infrastructure
(AMI) network that includes a plurality of AMI meters at a plurality of customer locations, the 5 head-end system comprising: a processor and a memory device accessible by said processor, said processor configured for: receiving, at the head-end system, at least one event signal from each of the
AMI meters, wherein the at least one event signal is indicative of at least one event occurring 10 at a corresponding customer location; determining, at the head-end system, whether to transmit at least one command signal to a corresponding AMI meter in response to receiving the at least one event signal from the corresponding AMI meter, wherein the at least one command signal is configured to instruct the corresponding AMI meter to perform at least one task in response to the at least 15 one event; and transmitting, at the head-end system, the at least one command signal to the corresponding AMI meter in response to determining to transmit the at least one command signal. 20 2. A head-end system in accordance with Claim 1, said memory device storing a database associating the at least one event with the at least one command signal, wherein to determine whether to transmit at least one command signal, said processor queries the database for the at least one event. 25 3. A head-end system in accordance with Claim 1 or 2, wherein said processor is further configured for transmitting at least one event-notification signal to at least one external management systems in response to receiving the at least one event signal, wherein the at least one event-notification signal is indicative of the at least one event occurring at the corresponding AMI meter.
4. A head-end system in accordance with Claim 1, said memory device storing a database associating the at least one event with the at least one command signal and the event-notification signal, wherein to determine whether to transmit at least one command signal, said processor queries the database for the at least one event.
5. A head-end system in accordance with Claim 3 or 4, wherein said processor is further configured for transmitting at least one command-notification signal to at least one of the external management systems in response to transmitting the at least one 5 command signal, wherein the at least one command-notification signal is indicative of the at least one command-signal being transmitted to the corresponding AMI meter.
6. A head-end system in accordance with Claim 5, said memory device storing a database associating the at least one event with the at least one command signal and 10 the event-notification signal, said database further associating the transmitting of the at least one command signal with the at least one command-notification, wherein to determine whether to transmit at least one command signal, said processor queries the database for the at least one event. 15
7. A method of responding to an event occurring at a customer location using a processor and a memory device of a head-end system of an advanced metering infrastructure, the method comprising: receiving at least one event signal from a AMI meter, wherein the at least one event signal is indicative of at least one event occurring at the customer location; 20 determining whether to transmit at least one command signal to the AMI meter in response to receiving the at least one event signal from the AMI meter, wherein the at least one command signal is configured to instruct the AMI meter to perform at least one task in response to the at least one event; and transmitting the at least one command signal to the AMI meter in response to 25 determining to transmit the at least one command signal.
8. A method in accordance with Claim 7, wherein said determining comprises querying a database stored in a memory device for the at least one event.
9. A method in accordance with Claim 7 or 8, further comprising transmitting at least one event-notification signal to at least one management system of an energy company in response to receiving the at least one event signal, wherein the at least one 5 event-notification signal is indicative of the at least one event occurring at the customer location.
10. A method in accordance with Claim 9, wherein said determining comprises querying a database stored in said memory device for the at least one event.
11. A method in accordance with any one of Claims 7 to 10, further comprising transmitting at least one command-notification signal to at least one of management system of an energy company in response to transmitting the at least one command signal, wherein the at least one command-notification signal is indicative of the at 15 least one command-signal being transmitted to the AMI meter.
12. A method in accordance with Claim 11, wherein said determining comprises querying a database stored in a memory device for the at least one event. 20
13. An event communication and response system comprising: a plurality of advanced metering infrastructure (AMI) meters; a head-end system communicatively coupled to the plurality of AMI meters, the head-end system comprising a processor and a memory device accessible by said processor; and 25 a plurality of management systems for managing data from the AMI meters, the plurality of management systems being communicatively coupled to the head-end system, wherein the processor of the head-end system is configured for: receiving at least one event signal from each of the AMI meters, wherein the at least one event signal is indicative of at least one event occurring at the corresponding AMI 30 meter; determining whether to transmit at least one command signal to a corresponding AMI meter in response to receiving the at least one event signal from the corresponding AMI meter, wherein the at least one command signal is configured to instruct the corresponding AMI meter to perform at least one task in response to the at least one event; transmitting the at least one command signal to the corresponding AMI meter in response to determining to transmit the at least one command signal. 5
14. An event communication and response system in accordance with Claim 13, wherein said memory device storing a database associating the at least one event with the at least one command signal, wherein to determine whether to transmit at least one command signal, said processor queries the database for the at least one event. 10
15. An event communication and response system in accordance with Claim 13 or 14, wherein said processor is further configured for transmitting at least one event-notification signal to at least one of the management systems in response to receiving the at least one event signal, wherein the at least one event-notification signal is indicative of the at least one event occurring at the corresponding AMI meter.
16. An event communication and response system in accordance with Claim 13 or 14, wherein said memory device storing a database associating the at least one event with the at least one command signal and the event-notification signal, wherein to determine whether to transmit at least one command signal, said processor queries the 20 database for the at least one event.
17. An event communication and response system in accordance with Claim 13 or 14, wherein said processor is further configured for transmitting at least one command-notification signal to at least one of said management systems in response to 25 transmitting the at least one command signal, wherein the at least one command-notification signal is indicative of the at least one command-signal being transmitted to the corresponding AMI meter.
18. An event communication and response system in accordance with 30 Claim 17, wherein said memory device storing a database associating the at least one event with the at least one command signal and the event-notification signal, said database further associating the transmitting of the at least one command signal with the at least one command- notification, wherein to determine whether to transmit at least one command signal, said processor queries the database for the at least one event.
19. A head-end system for use with an advanced metering infrastructure (AMI) network substantially as hereinbefore described with reference to any one of the embodiments shown in the drawings.
20. A method of responding to an event occurring at a customer location using a processor of a head-end system of an advanced metering infrastructure substantially as hereinbefore described with reference to any one of the embodiments shown in the drawings.
Applications Claiming Priority (2)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
US13/113,674 US20120299744A1 (en) | 2011-05-23 | 2011-05-23 | Head-end system for advanced metering infrastructure network |
US13/113,674 | 2011-05-23 |
Publications (2)
Publication Number | Publication Date |
---|---|
NZ600150A NZ600150A (en) | 2013-11-29 |
NZ600150B true NZ600150B (en) | 2014-03-04 |
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