CA2301700A1 - Electronic electricity meter - Google Patents
Electronic electricity meter Download PDFInfo
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- CA2301700A1 CA2301700A1 CA002301700A CA2301700A CA2301700A1 CA 2301700 A1 CA2301700 A1 CA 2301700A1 CA 002301700 A CA002301700 A CA 002301700A CA 2301700 A CA2301700 A CA 2301700A CA 2301700 A1 CA2301700 A1 CA 2301700A1
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- modem
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- G—PHYSICS
- G06—COMPUTING; CALCULATING OR COUNTING
- G06Q—INFORMATION AND COMMUNICATION TECHNOLOGY [ICT] SPECIALLY ADAPTED FOR ADMINISTRATIVE, COMMERCIAL, FINANCIAL, MANAGERIAL OR SUPERVISORY PURPOSES; SYSTEMS OR METHODS SPECIALLY ADAPTED FOR ADMINISTRATIVE, COMMERCIAL, FINANCIAL, MANAGERIAL OR SUPERVISORY PURPOSES, NOT OTHERWISE PROVIDED FOR
- G06Q20/00—Payment architectures, schemes or protocols
- G06Q20/08—Payment architectures
- G06Q20/12—Payment architectures specially adapted for electronic shopping systems
- G06Q20/127—Shopping or accessing services according to a time-limitation
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01R—MEASURING ELECTRIC VARIABLES; MEASURING MAGNETIC VARIABLES
- G01R21/00—Arrangements for measuring electric power or power factor
- G01R21/133—Arrangements for measuring electric power or power factor by using digital technique
-
- G—PHYSICS
- G07—CHECKING-DEVICES
- G07F—COIN-FREED OR LIKE APPARATUS
- G07F15/00—Coin-freed apparatus with meter-controlled dispensing of liquid, gas or electricity
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- G—PHYSICS
- G07—CHECKING-DEVICES
- G07F—COIN-FREED OR LIKE APPARATUS
- G07F17/00—Coin-freed apparatus for hiring articles; Coin-freed facilities or services
- G07F17/0014—Coin-freed apparatus for hiring articles; Coin-freed facilities or services for vending, access and use of specific services not covered anywhere else in G07F17/00
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Abstract
An electronic electricity meter which, in one embodiment, includes a modem board, or unit, coupled to the meter microcomputer (20) and exchanges information between the meter (10) and a central computer (58) is described.
Using signals supplied by the meter microcomputer (20) and the central computer (58), the modem unit (50) microcomputer can determine whether to exchange information between the meter and the central computer (58) and the proper time at which the information should be exchanged. In an exemplary embodiment, the modem unit (50) detects various conditions within the meter and responds by exchanging information with the central computer (58) at a proper, or pre-defined, time. The modem unit has two different basic modes, or states, of operation. These states of operation are sometimes referred to as the call originate mode and the call answer mode. Call originate refers to the mode of the unit when a condition occurs in meter 10 and information is being transmitted to the central computer (58) from the modem unit (50) utilizing a telephone line. The call is originated upon occurrence, for example of a power outage to the meter. In the call answer mode, the central computer originates a call to the meter. The central computer (58) can then transfer information to the meter, for example a new program can be stored in the modem unit memory.
Using signals supplied by the meter microcomputer (20) and the central computer (58), the modem unit (50) microcomputer can determine whether to exchange information between the meter and the central computer (58) and the proper time at which the information should be exchanged. In an exemplary embodiment, the modem unit (50) detects various conditions within the meter and responds by exchanging information with the central computer (58) at a proper, or pre-defined, time. The modem unit has two different basic modes, or states, of operation. These states of operation are sometimes referred to as the call originate mode and the call answer mode. Call originate refers to the mode of the unit when a condition occurs in meter 10 and information is being transmitted to the central computer (58) from the modem unit (50) utilizing a telephone line. The call is originated upon occurrence, for example of a power outage to the meter. In the call answer mode, the central computer originates a call to the meter. The central computer (58) can then transfer information to the meter, for example a new program can be stored in the modem unit memory.
Description
ELECTRONIC ELECTRICITY METER
CROSS REFERENCE TO RELATED APPLICATION
This application claims the benefit of U.S. Provisional Application No.
60/091,039, filed June 29, 1998.
BACKROUND OF THE INVENTION
This invention relates generally to electricity metering and more particularly, to an electronic electricity meter configurable to transmit information to a central computer via a modem unit.
In many electron~.ic electricity meters, communications with a meter microcomputer can be performed via an optical port or an option board connector.
For example, in some known meters, an electrical connector is provided so that various option boards, such as a telephone modem communication board, may be electrically connected to the meter microcomputer. A central computer is often used to collect data, including billing information, fmm the meter, using the modem communication board. The data is available from the modem communication board in a predefined format (an ANSI defined protocol) on the communication channel which connects the option board connector to the meter microcomputer.
is To reduce the number of nuisance and common event, e. g. , power outage, calls, it is desirable to provide a modem unit, or board, which detects conditions within the meter and exchanges information with the central computer after the condition has existed for a pre-defined period of time. It also would be desirable to pmvide such a unit that would allow modification of the operation parameters.
It 2o would further be desirable to provide such a modem unit which can be easily and quickly coupled to a meter while allowing programming of a security password.
BRIEF SUMMARY OF THE INVENTION
In an exemplary embodiment, an electricity meter includes a modem circuit, or unit, coupled to the meter microcomputer which exchanges information between the meter microcomputer and a central computer of the data source. Using the signals supplied by the meter microcomputer and the central computer, the modem unit can detect various conditions within the meter and determine the proper time for exchanging the information. In one embodiment, the modem unit includes a microcomputer having a plurality of timers.
In one aspect, the present invention is directed to allowing the programming of meter and modem unit passwords. Specifically, the meter and modem unit are placed into a password recovery state upon detecting closure of an external switch.
Closure of the external switch simultaneously places the meter and the modem unit into password recovery states so that new passwords may be programmed into the meter and the modem unit by the central computer. Such a configuration avoids the 1s time and expense associated with reprogramming the modem unit at the meter shop or having to send a specially trained individual to the meter site to perform the reprogramming.
In another aspect, the present invention is directed to limiting the number of calls initiated from the meter. More specifically, the modem unit microcomputer 2o detects certain events and waits a pre-defined period of time before initiating the call to the central computer. In one form, after the modem unit detects a power outage indicator from the meter microcomputer, the modem unit waits a programmable period of time prior to an outage call being placed to the central computer.
The modem unit microcomputer may be further configured so that in order to initiate the 2s call to the central computer several conditions must occur within a pre-defined period of time. If all of the events do not occur in the specified period of time, the call will not be made to the central computer.
CROSS REFERENCE TO RELATED APPLICATION
This application claims the benefit of U.S. Provisional Application No.
60/091,039, filed June 29, 1998.
BACKROUND OF THE INVENTION
This invention relates generally to electricity metering and more particularly, to an electronic electricity meter configurable to transmit information to a central computer via a modem unit.
In many electron~.ic electricity meters, communications with a meter microcomputer can be performed via an optical port or an option board connector.
For example, in some known meters, an electrical connector is provided so that various option boards, such as a telephone modem communication board, may be electrically connected to the meter microcomputer. A central computer is often used to collect data, including billing information, fmm the meter, using the modem communication board. The data is available from the modem communication board in a predefined format (an ANSI defined protocol) on the communication channel which connects the option board connector to the meter microcomputer.
is To reduce the number of nuisance and common event, e. g. , power outage, calls, it is desirable to provide a modem unit, or board, which detects conditions within the meter and exchanges information with the central computer after the condition has existed for a pre-defined period of time. It also would be desirable to pmvide such a unit that would allow modification of the operation parameters.
It 2o would further be desirable to provide such a modem unit which can be easily and quickly coupled to a meter while allowing programming of a security password.
BRIEF SUMMARY OF THE INVENTION
In an exemplary embodiment, an electricity meter includes a modem circuit, or unit, coupled to the meter microcomputer which exchanges information between the meter microcomputer and a central computer of the data source. Using the signals supplied by the meter microcomputer and the central computer, the modem unit can detect various conditions within the meter and determine the proper time for exchanging the information. In one embodiment, the modem unit includes a microcomputer having a plurality of timers.
In one aspect, the present invention is directed to allowing the programming of meter and modem unit passwords. Specifically, the meter and modem unit are placed into a password recovery state upon detecting closure of an external switch.
Closure of the external switch simultaneously places the meter and the modem unit into password recovery states so that new passwords may be programmed into the meter and the modem unit by the central computer. Such a configuration avoids the 1s time and expense associated with reprogramming the modem unit at the meter shop or having to send a specially trained individual to the meter site to perform the reprogramming.
In another aspect, the present invention is directed to limiting the number of calls initiated from the meter. More specifically, the modem unit microcomputer 2o detects certain events and waits a pre-defined period of time before initiating the call to the central computer. In one form, after the modem unit detects a power outage indicator from the meter microcomputer, the modem unit waits a programmable period of time prior to an outage call being placed to the central computer.
The modem unit microcomputer may be further configured so that in order to initiate the 2s call to the central computer several conditions must occur within a pre-defined period of time. If all of the events do not occur in the specified period of time, the call will not be made to the central computer.
In yet another aspect, the present invention is directed to the modem unit answering calls from the central computer. More specifically, and in accordance with one form, the meter modem unit receives new program information from the central computer. The modem unit microcomputer program is stored in a non-volatile memory having two segments. A new program is stored in an inactive segment of the memory while the modem unit microcomputer executes a program from the active segment. If the programming is completed, the microcomputer changes the inactive segment to the active segment and executes the new program.
However, if the programming is not completed, the modem unit microcomputer will continue to execute the pmgram stored in the active segment. The two segments ensure that the meter will not be left in a partially programmed mode.
In still another aspect, the present invention is directed to utilizing multiple meters configured in a master slave arrangement. Information is exchanged between the meters and the central computer utilizing a single telephone line.
More ~s specifically, each meter includes a modem unit having a unique identification number. Prior to exchanging information from the central computer, an identification number is transferred to the meters. Each modem microcomputer determines whether the transferred identification number matches the identification number stored in its memory. If the numbers match, that modem unit exchanges 2o information with the central computer. Those meters which do not match the transferred identification number wait and listen for the next transferred identification number to determine whether a match exists.
The above described modem unit detects multiple conditions and responds to those conditions at the pmper pre-defined time to reduce the number of nuisance and 2s common event calls. New operation parameters may also be transferred to the modem unit to allow modification of the condition and time parameters. The modem unit described above allows the password to be reprogrammed and the user does not have to pre-program the modem unit. As result, a new modem unit may be quickly installed in a meter.
BRIEF DESCRIPTION OF THE DRAWINGS
Figure 1 is a block diagram of an electronic energy meter.
Figure 2 is a block diagram of a modem unit in accordance with one embodiment of the present invention.
Figure 3 is a flow chart of operation of the meter in accordance with one embodiment of the present invention.
Figure 4 is a flow chart illustrating a sequence of process steps for detecting a condition in an electronic electricity meter.
o Figure 5 is a flow chart illustrating a sequence of process steps for detecting a password recovery state in an electronic electricity meter.
Figure 6 is a flow chart illustrating a sequence of process steps for detecting a power outage state in an electronic electricity meter.
Figure 7 is a flow chart illustrating a sequence of process steps for placing an 15 outage call in an electronic electricity meter.
Figure 8 is a flow chart illustrating a sequence of process steps for generating a status report in an electronic electricity meter.
Figure 9 is a flow chart illustrating a sequence of process steps for call answer state in an electronic electricity meter.
2o Figure 10 is a block diagram of a master/slave configuration in accordance with one embodiment of the present invention.
However, if the programming is not completed, the modem unit microcomputer will continue to execute the pmgram stored in the active segment. The two segments ensure that the meter will not be left in a partially programmed mode.
In still another aspect, the present invention is directed to utilizing multiple meters configured in a master slave arrangement. Information is exchanged between the meters and the central computer utilizing a single telephone line.
More ~s specifically, each meter includes a modem unit having a unique identification number. Prior to exchanging information from the central computer, an identification number is transferred to the meters. Each modem microcomputer determines whether the transferred identification number matches the identification number stored in its memory. If the numbers match, that modem unit exchanges 2o information with the central computer. Those meters which do not match the transferred identification number wait and listen for the next transferred identification number to determine whether a match exists.
The above described modem unit detects multiple conditions and responds to those conditions at the pmper pre-defined time to reduce the number of nuisance and 2s common event calls. New operation parameters may also be transferred to the modem unit to allow modification of the condition and time parameters. The modem unit described above allows the password to be reprogrammed and the user does not have to pre-program the modem unit. As result, a new modem unit may be quickly installed in a meter.
BRIEF DESCRIPTION OF THE DRAWINGS
Figure 1 is a block diagram of an electronic energy meter.
Figure 2 is a block diagram of a modem unit in accordance with one embodiment of the present invention.
Figure 3 is a flow chart of operation of the meter in accordance with one embodiment of the present invention.
Figure 4 is a flow chart illustrating a sequence of process steps for detecting a condition in an electronic electricity meter.
o Figure 5 is a flow chart illustrating a sequence of process steps for detecting a password recovery state in an electronic electricity meter.
Figure 6 is a flow chart illustrating a sequence of process steps for detecting a power outage state in an electronic electricity meter.
Figure 7 is a flow chart illustrating a sequence of process steps for placing an 15 outage call in an electronic electricity meter.
Figure 8 is a flow chart illustrating a sequence of process steps for generating a status report in an electronic electricity meter.
Figure 9 is a flow chart illustrating a sequence of process steps for call answer state in an electronic electricity meter.
2o Figure 10 is a block diagram of a master/slave configuration in accordance with one embodiment of the present invention.
Figure 11 is a flow chart illustrating a sequence of process steps for a masterlslave configuration of an electronic electricity meter.
DETAILED DESCRIPTION OF THE DRAW~TGS
Figure 1 is a block diagram illustration of an exemplary electronic energy meter 10 which, for example, is commercially available fpm General Electric s Company, 130 Main Street, Somersworth, N.H. 03878, and generally referred to as the KV meter. The KV meter can be modified to incorporate the modem unit described below in more detail. Although the present apparatus and methods are described herein in the context of an electronic electricity meter, it should be understood that the present invention is not limited to practice with any one 1o particular meter. The present invention can be utilized in connection with other microcomputer based meters.
Referring now specifically to Figure 1, meter 10 includes voltage sensors 12 and current sensors 14. Sensors 12 and 14, in operation, typically are coupled to the power lines supplying power to site at which the meter is located. Sensors ~s and 14 are coupled to an analog to digital (AID) converter 16 which converts the input analog voltage and current signal to digital signals. The output of converter 16 is provided to a digital signal processor (DSP) 18. DSP 18 supplies microcomputer 20 with digitized metering quantities, e.g., VZH, I2H.
Microcomputer 20, using the metering quantities supplied by DSP 18, performs 2o additional metering calculations and functions. DSP 18 may, for example, be a processor commercially available as Model Number TMS320 from Texas Instruments Company, P.O. Box 6102, Mail Station 3244, Temple, TX 76503, modified to perform metering functions.
Microcomputer 20 is coupled to a liquid crystal display 22 to control the 25 display of various selected metering quantities and to an optical communications port 24 to enable an external reader to communicate with computer 20. Port 24 may be the well known OPTOCOM~ port of General Electric Company, 130 Main Street, Somersworth, N.H. 03878, which is in accordance with the ANSI type II
optical port. Microcomputer 20 may also generate additional outputs 26 used for various other functions as is well known in the art. Microcomputer 20 may, for s example, be an eight bit microcomputer commercially available from Hitachi America, inc., Semiconductor & LC. Division, Hitachi Plaza, 2000 Sierra Point Parkway, Brisbane, CA 94005-1819, modified to perform metering functions.
Microcomputer 20, in one embodiment, also is coupled to an inputloutput (I/O) board 28 and to a function, or high function, board 30. DSP 18 also supplies outputs directly to high function board 30. Microcomputer 20 further is coupled, via a control bus 32, to an electronically erasable programmable read only memory (EEPROM) 34. I/O board 28 and high function board 30 also are coupled, via bus 32, to EEPROM 34.
Back-up power is supplied to the meter 10 by a power outage battery 36 1s coupled to a wide range power supply 38. In normal operation when no back-up power is required, power is supplied to the meter components from the power lines via power supply 38.
Many functions and modifications of the components described above are well understood in the metering art. The present application is not directed to such 2o understood and known functions and modifications. Rather, the present application is directed to the methods and structures described below in more detail. In addition, although the methods and structures are described below in the hardware environment shown in connection with Figure 1, it should be understood that such methods and structures are not limited to practice in such environment. The subject 25 methods and structures could be practiced in many other environments.
Further, it should be understood that the present invention can be practiced with many alternative microcomputers, and is not limited to practice in connection with just microcomputer 20. Therefore, and as used herein, the term microcomputer is not limited to mean just those integrated circuits referred to in the art as microcomputers, but broadly refers to microcomputers, processors, microcontrollers, application specific integrated circuits, and other programmable circuits.
Figure 2 is a block diagram of an exemplary modem circuit, or unit, 50 in accordance with one embodiment of the present invention. Generally, unit 50 couples to meter microcomputer 20 as described below in more detail and at least based in part on the signals present at unit 50, unit 50 can determine whether meter 10 should take any action as described below.
Referring now specifically to Figure 2, unit 50 includes a microcomputer 52 coupled to meter microcomputer 20, a memory 54, and a modem circuit 56. Unit 50 provides a communication path, or link, for exchanging data, or information, between meter 10 and a central computer 58. Microcomputer 52 includes, in one embodiment, a random access memory (RAM) 60 and a read only memory (ROM) 62. Programmed parameters and operating information, or data (not shown), are stored in memory 54. Memory 54 may, for example, be a non-volatile memory device such as an electrically erasable read only memory (P.EPROM), although other types of non-volatile memory devices may be used. Modem circuit 56 may, 2o for example, be a modem chipset commercially available as Model Number RC224AT from Rockwell International Corp. , Digital Communications Division, 4311 Jamboree Road, Newport Beach, CA 92660.
Command, response, and communication data are exchanged between microcomputer 52 and modem circuit 56. A telephone interface circuit 64 couples 2s modem circuit 56 to a telephone line 66 so that information may be remotely exchanged between meter 10 and central computer 58. In one embodiment, modem unit microcomputer includes a timer circuit 80 having a plurality of timer circuits for measuring time. Timer circuit 80 includes a real-time clock 82, an outage timer 84, an outage delay timer 86, and a call delay timer 88. Real-time clock 82 generates a time value representative of the current time and date, e.g., HH:MM:SS, MM/DD/YY. Timers 84, 86, and 88 are used for measuring the s amount of time that has passed since a certain event, or occurrence of a condition.
Timers 84, 86, and 88 may be programmed with an initial value and may increment or decrement in value and produce a signal when the programmed time has passed or elapsed. In an alternative embodiment, timer circuit 80 may be separate and distinct from modem unit nucrocomputer 52.
o To exchange information between meter 10 and central computer 58, and in one embodiment, a data exchange algorithm is loaded into modem unit 50.
Specifically, the algorithm is loaded, and stored, in memory 62. The algorithm is then executed by microcomputer 52.
A flow chart 100 illustrating process steps executed by microcomputer 52 in 15 exchanging information between meter 10 and central computer 58 is set forth in Figure 3. More particularly, upon power up 102 of meter 10, or anytime after power is applied to meter 10, various parameters are programmed 104 into memory 54. In one embodiment, the parameters include initial values for timer circuits 80, specifically, initialization of timers 84, 86, and 88, whether an outage call should be 2o placed, how long should meter 10 wait before placing call, and whether meter IO
should answer a call from the central computer 58. In addition, after the parameters are programmed and power is appfied to meter 10, outage delay timer 86 is started.
After programming parameters 104, microcomputer 52 monitors operations of meter 10 to determine, or detect, whether a condition exists, or a change has 25 occurred 106 in the signals provided to modem unit 50. The conditions include an error, a caution, and a diagnostic condition. If a condition is detected 106, information is transferred, or exchanged, 108 using modem unit 50.
Particularly, microcomputer S2 detects modifications of signals provided from meter microcomputer 20 to modem microcomputer 52 and in the signals provided from central computer 58. More specifically as shown in Figure 4, microcomputer 52 detects 106 at least the following the conditions or changes and exchanges 108 the indicated information.
Detect Condition 106 Information Exchange 108 1. Password Recovery 110 Recover password 114.
2. Power outage 118 Power outage call 122.
3. Scheduled Status Report 126 Status Call 130 4. Call from central computer 134 Answer Call 138.
5. New Program 142 Update Program 146.
6. Master/Slave mode 150 Master/Slave Update 154 Password Recovery and Recover Password Password recovery 110 and recover password 112 refer to detecting a 1s password recovery state and enabling programming of modem unit 50 password and meter 10 password. In one embodiment, an external switch, oerable by a user, generates a PW Recovery signal that is supplied to modem unit 50 from meter microcomputer 20. The PW Recovery signal is supplied to microcomputer 52 in a low to high state to enable the programming of the passwords. More particularly, 2o and referring to Figure 5, recovering password 114 includes disabling the password security 200 of modem unit 50 and placing modem unit 50 in a password recovery state 202. Disabling security 200 allows microcomputer 52 of modem unit 50 to continue to operate without having a password that matches the meter password.
After modem unit 50 is placed in the recovery state 202, the same password is stored 204 in meter 10 and modem unit 50. Specifically, the passwords transmitted from central computer 58 to meter 10 utivzixig modem unit 50. The passwords are then programmed in meter microcomputer 20 and modem unit memory 54. Upon completion of programming the new passwords into microcomputer 20 and memory 54, the PW_Recovery signal supplied to microcomputer 52 is changed to a false, or low state by meter microcomputer 20. Password security of modem unit 50 is enabled 208 after modem unit 50 receives the new passwords.
For example, if a new modem unit 50 is installed and coupled to a microcomputer 20, the meter password and the modem unit password would not to match, therefore, meter 10 may not be able to be programmed to extend the functionality of meter 10. As a result of recover password 114, modem unit 50 and microcomputer 20 will have matching passwords.
Power outage and~ower outage call Power outage 118 and power outage call 122 refers to notifying central computer 58 when the power is removed from meter 10. A power outage signal is supplied to modem unit 50 from meter microcomputer 20 to indicate that power has been removed from meter 10. Specifically, the power outage signal supplied by microcomputer 20 changes from a false state, to a tnle state when power is removed from meter 10. More specifically and as shown in Figure 6, upon microcomputer 52 detecting power outage 118, power is supplied 220 to microcomputer 52 from outage battery 36. Microcomputer 52 updates 222 a meter status signal which is stored in memory 54. Outage timer 84 is then started 224 and the outage delay timer is stopped and the value stored 226 in memory 54. The value of outage timer 84 is then monitored 228 using microcomputer 54 to determine whether the value of outage timer 84 is within a valid range. If power is not restored to meter 10 prior to the value of outage timer 84 being within the valid range, microcomputer 52 examines 230 previous outage call completed parameter stored in memory 54 to determine whether an outage call should be placed. If the previous outage call completed parameter stored in memory 54 is in a false state, a call is placed 232 to central computer 58 as described below. If, however, the previous outage call completed parameter is in a true state, microcomputer 52 examines 234 the value of outage delay timer 86 stored in memory 54 to determine whether the value is within a predefined, or valid range. If the value is within the predefined range, a call is placed to central computer 58. If, however, the value is outside the valid range, microcomputer 52 resets 238 outage delay timer 86 and waits for power to be applied to meter 10.
io Outage timer 84 and outage delay timer 86 may be co~gured to avoid nuisance outages calls caused by power transients and to alter the timing of outage calls from different meters in a common outage area. Specifically, outage timer $4 may be configured to prevent calls from being made to central computer 58 until a specific amount of time has passed. In one embodiment, outage timer 84 is 1s programmed with a value between 0, indicating no delay, and 255 seconds. If the value is programmed with a non-zero value, power must be removed from meter 10 at least for that period, or valid range, of time, before microcomputer 52 proceeds.
For example, in one embodiment, diagnostic tests, or checks, are delayed a selectable period of time to allow stabilization of supplying power and meter 10. In 2o another embodiment, calls to central compute 58 are prevented until the selected period of time for stabilization has passed.
The value of outage timer 84 is altered to prevent nuisance calls from being generated from power outages having a duration iess than the programmed value of timer 84. In addition, outage delay timer 86 may be configured to prevent nuisance 25 calls from transient conditions. For example, typical outages may consist of a series of power transitions before power is completely lost and short outages may occur during normal operation due to wind blown power lines or other relatively brief disturbances. Additionally, the process of repairing local power distribution faults often produces several brief power restorations, followed by a loss of power, before power is restored permanently. In order to avoid multiple calls from being made from a plurality of meters, outage timer 84 and outage delay timer 86 may be configured to require that power be removed for a pre-defined period of time and meter 10 to have power applied for a valid range of time before an outage call is made. Specifically, if the values of both timers 84 and 86 are not within their respective valid ranges a call will not be placed to central computer 56.
Referring to Figure 7, in placing a call 236 to central computer 58, microcomputer 52 initializes 250 modem circuit 56: Initialization 250 includes configuring circuit 56 to originate a call to central computer 58, defines a phone number to call for central computer 58, and defining parameters related to the baud rate, type of handshaking and other communication parameters as known in the art.
If the outage call parameter is in a true state indicating that a call is to be made during a power outage condition, microcomputer 52 delays 252 a defined period of ~s time for outage battery 36 to reach full charge. Call delay timer 88 is started 254 and microcomputer 52 monitors 256 call delay timer 88 until the value of call timer equals the value, or valid range, defined during programming of parameters 104.
When the value of call delay timer is within the valid range, a status report is generated 258 by microcomputer 52 and a call is placed 260 to central computer 2o utilizing modem circuit 56. After the status report is generated 258, modem circuit 56 supplies the status report to telephone interface 64 and telephone line 66 so that the status report is transferred to central compute 58. If a call is completed 262, modem circuit 56 supplies 264 an outage call completed signal to microcomputer and power is removed 266 from modem circuit 56.
2s If the call is not completed, call delay timer 88 is reset and started 268.
Upon microcomputer 52 detecting 270 call delay timer 88 being within a valid range, a second call is placed 272 to central computer 58. The second call may be placed to the same phone number as described above, or may be placed to a second phone number for central computer 58. As described above, if microcomputer 52 detects 274 that the second call was completed, modem circuit 56 supplies 262 the outage call completed signal to microcomputer 52 and power is removed 264 from modem circuit 56. If the call is not completed, modem unit 50 is stopped and waits s for power to be applied to meter 10. Additional configurations may also be included, e. g. , meter 10 may attempt any number of calls and any number of different numbers prior to stopping.
In one embodiment and as shown in Figure 8, the status report generated 258 includes transferring status information, or data, from two tables stored in memory 54. Specifically, microcomputer 20 periodically executes a diagnostic, or test routine to update 300 status of meter 10. The results of the diagnostic routine is transferred from microcomputer 20 to microcomputer 52 and stored 302 in a meter status table in memory 54. A modem unit status routine is executed by microcomputer 52 to update 304 status of modem unit 50. The resulting modem 1s unit status is stored in a modem status table in memory 54. The status report generated 258 for transfer to central computer 58, includes the contents of the meter status table and the modem unit status table.
In another aspect of the present invention, in order to reduce the power consumption of outage battery 36, outage battery 36 powers only modem unit 50 2o during a power outage. Specifically, in the event of a power outage, before placing 260 call to central computer 58, microcomputer 52 updates the modem status table and stores the updated status in memory. Then, unneeded circuitry is placed in a low power sleep mode, until the outage call is placed. Once modem unit 50 is connected to central computer 58, the status report, including all required status 2s information is exchanged with to central computer 58 by transferring the meter status table and the modem status table. As a result, the time required to transmit the information is reduced which reduces power consumption of outage battery 36.
DETAILED DESCRIPTION OF THE DRAW~TGS
Figure 1 is a block diagram illustration of an exemplary electronic energy meter 10 which, for example, is commercially available fpm General Electric s Company, 130 Main Street, Somersworth, N.H. 03878, and generally referred to as the KV meter. The KV meter can be modified to incorporate the modem unit described below in more detail. Although the present apparatus and methods are described herein in the context of an electronic electricity meter, it should be understood that the present invention is not limited to practice with any one 1o particular meter. The present invention can be utilized in connection with other microcomputer based meters.
Referring now specifically to Figure 1, meter 10 includes voltage sensors 12 and current sensors 14. Sensors 12 and 14, in operation, typically are coupled to the power lines supplying power to site at which the meter is located. Sensors ~s and 14 are coupled to an analog to digital (AID) converter 16 which converts the input analog voltage and current signal to digital signals. The output of converter 16 is provided to a digital signal processor (DSP) 18. DSP 18 supplies microcomputer 20 with digitized metering quantities, e.g., VZH, I2H.
Microcomputer 20, using the metering quantities supplied by DSP 18, performs 2o additional metering calculations and functions. DSP 18 may, for example, be a processor commercially available as Model Number TMS320 from Texas Instruments Company, P.O. Box 6102, Mail Station 3244, Temple, TX 76503, modified to perform metering functions.
Microcomputer 20 is coupled to a liquid crystal display 22 to control the 25 display of various selected metering quantities and to an optical communications port 24 to enable an external reader to communicate with computer 20. Port 24 may be the well known OPTOCOM~ port of General Electric Company, 130 Main Street, Somersworth, N.H. 03878, which is in accordance with the ANSI type II
optical port. Microcomputer 20 may also generate additional outputs 26 used for various other functions as is well known in the art. Microcomputer 20 may, for s example, be an eight bit microcomputer commercially available from Hitachi America, inc., Semiconductor & LC. Division, Hitachi Plaza, 2000 Sierra Point Parkway, Brisbane, CA 94005-1819, modified to perform metering functions.
Microcomputer 20, in one embodiment, also is coupled to an inputloutput (I/O) board 28 and to a function, or high function, board 30. DSP 18 also supplies outputs directly to high function board 30. Microcomputer 20 further is coupled, via a control bus 32, to an electronically erasable programmable read only memory (EEPROM) 34. I/O board 28 and high function board 30 also are coupled, via bus 32, to EEPROM 34.
Back-up power is supplied to the meter 10 by a power outage battery 36 1s coupled to a wide range power supply 38. In normal operation when no back-up power is required, power is supplied to the meter components from the power lines via power supply 38.
Many functions and modifications of the components described above are well understood in the metering art. The present application is not directed to such 2o understood and known functions and modifications. Rather, the present application is directed to the methods and structures described below in more detail. In addition, although the methods and structures are described below in the hardware environment shown in connection with Figure 1, it should be understood that such methods and structures are not limited to practice in such environment. The subject 25 methods and structures could be practiced in many other environments.
Further, it should be understood that the present invention can be practiced with many alternative microcomputers, and is not limited to practice in connection with just microcomputer 20. Therefore, and as used herein, the term microcomputer is not limited to mean just those integrated circuits referred to in the art as microcomputers, but broadly refers to microcomputers, processors, microcontrollers, application specific integrated circuits, and other programmable circuits.
Figure 2 is a block diagram of an exemplary modem circuit, or unit, 50 in accordance with one embodiment of the present invention. Generally, unit 50 couples to meter microcomputer 20 as described below in more detail and at least based in part on the signals present at unit 50, unit 50 can determine whether meter 10 should take any action as described below.
Referring now specifically to Figure 2, unit 50 includes a microcomputer 52 coupled to meter microcomputer 20, a memory 54, and a modem circuit 56. Unit 50 provides a communication path, or link, for exchanging data, or information, between meter 10 and a central computer 58. Microcomputer 52 includes, in one embodiment, a random access memory (RAM) 60 and a read only memory (ROM) 62. Programmed parameters and operating information, or data (not shown), are stored in memory 54. Memory 54 may, for example, be a non-volatile memory device such as an electrically erasable read only memory (P.EPROM), although other types of non-volatile memory devices may be used. Modem circuit 56 may, 2o for example, be a modem chipset commercially available as Model Number RC224AT from Rockwell International Corp. , Digital Communications Division, 4311 Jamboree Road, Newport Beach, CA 92660.
Command, response, and communication data are exchanged between microcomputer 52 and modem circuit 56. A telephone interface circuit 64 couples 2s modem circuit 56 to a telephone line 66 so that information may be remotely exchanged between meter 10 and central computer 58. In one embodiment, modem unit microcomputer includes a timer circuit 80 having a plurality of timer circuits for measuring time. Timer circuit 80 includes a real-time clock 82, an outage timer 84, an outage delay timer 86, and a call delay timer 88. Real-time clock 82 generates a time value representative of the current time and date, e.g., HH:MM:SS, MM/DD/YY. Timers 84, 86, and 88 are used for measuring the s amount of time that has passed since a certain event, or occurrence of a condition.
Timers 84, 86, and 88 may be programmed with an initial value and may increment or decrement in value and produce a signal when the programmed time has passed or elapsed. In an alternative embodiment, timer circuit 80 may be separate and distinct from modem unit nucrocomputer 52.
o To exchange information between meter 10 and central computer 58, and in one embodiment, a data exchange algorithm is loaded into modem unit 50.
Specifically, the algorithm is loaded, and stored, in memory 62. The algorithm is then executed by microcomputer 52.
A flow chart 100 illustrating process steps executed by microcomputer 52 in 15 exchanging information between meter 10 and central computer 58 is set forth in Figure 3. More particularly, upon power up 102 of meter 10, or anytime after power is applied to meter 10, various parameters are programmed 104 into memory 54. In one embodiment, the parameters include initial values for timer circuits 80, specifically, initialization of timers 84, 86, and 88, whether an outage call should be 2o placed, how long should meter 10 wait before placing call, and whether meter IO
should answer a call from the central computer 58. In addition, after the parameters are programmed and power is appfied to meter 10, outage delay timer 86 is started.
After programming parameters 104, microcomputer 52 monitors operations of meter 10 to determine, or detect, whether a condition exists, or a change has 25 occurred 106 in the signals provided to modem unit 50. The conditions include an error, a caution, and a diagnostic condition. If a condition is detected 106, information is transferred, or exchanged, 108 using modem unit 50.
Particularly, microcomputer S2 detects modifications of signals provided from meter microcomputer 20 to modem microcomputer 52 and in the signals provided from central computer 58. More specifically as shown in Figure 4, microcomputer 52 detects 106 at least the following the conditions or changes and exchanges 108 the indicated information.
Detect Condition 106 Information Exchange 108 1. Password Recovery 110 Recover password 114.
2. Power outage 118 Power outage call 122.
3. Scheduled Status Report 126 Status Call 130 4. Call from central computer 134 Answer Call 138.
5. New Program 142 Update Program 146.
6. Master/Slave mode 150 Master/Slave Update 154 Password Recovery and Recover Password Password recovery 110 and recover password 112 refer to detecting a 1s password recovery state and enabling programming of modem unit 50 password and meter 10 password. In one embodiment, an external switch, oerable by a user, generates a PW Recovery signal that is supplied to modem unit 50 from meter microcomputer 20. The PW Recovery signal is supplied to microcomputer 52 in a low to high state to enable the programming of the passwords. More particularly, 2o and referring to Figure 5, recovering password 114 includes disabling the password security 200 of modem unit 50 and placing modem unit 50 in a password recovery state 202. Disabling security 200 allows microcomputer 52 of modem unit 50 to continue to operate without having a password that matches the meter password.
After modem unit 50 is placed in the recovery state 202, the same password is stored 204 in meter 10 and modem unit 50. Specifically, the passwords transmitted from central computer 58 to meter 10 utivzixig modem unit 50. The passwords are then programmed in meter microcomputer 20 and modem unit memory 54. Upon completion of programming the new passwords into microcomputer 20 and memory 54, the PW_Recovery signal supplied to microcomputer 52 is changed to a false, or low state by meter microcomputer 20. Password security of modem unit 50 is enabled 208 after modem unit 50 receives the new passwords.
For example, if a new modem unit 50 is installed and coupled to a microcomputer 20, the meter password and the modem unit password would not to match, therefore, meter 10 may not be able to be programmed to extend the functionality of meter 10. As a result of recover password 114, modem unit 50 and microcomputer 20 will have matching passwords.
Power outage and~ower outage call Power outage 118 and power outage call 122 refers to notifying central computer 58 when the power is removed from meter 10. A power outage signal is supplied to modem unit 50 from meter microcomputer 20 to indicate that power has been removed from meter 10. Specifically, the power outage signal supplied by microcomputer 20 changes from a false state, to a tnle state when power is removed from meter 10. More specifically and as shown in Figure 6, upon microcomputer 52 detecting power outage 118, power is supplied 220 to microcomputer 52 from outage battery 36. Microcomputer 52 updates 222 a meter status signal which is stored in memory 54. Outage timer 84 is then started 224 and the outage delay timer is stopped and the value stored 226 in memory 54. The value of outage timer 84 is then monitored 228 using microcomputer 54 to determine whether the value of outage timer 84 is within a valid range. If power is not restored to meter 10 prior to the value of outage timer 84 being within the valid range, microcomputer 52 examines 230 previous outage call completed parameter stored in memory 54 to determine whether an outage call should be placed. If the previous outage call completed parameter stored in memory 54 is in a false state, a call is placed 232 to central computer 58 as described below. If, however, the previous outage call completed parameter is in a true state, microcomputer 52 examines 234 the value of outage delay timer 86 stored in memory 54 to determine whether the value is within a predefined, or valid range. If the value is within the predefined range, a call is placed to central computer 58. If, however, the value is outside the valid range, microcomputer 52 resets 238 outage delay timer 86 and waits for power to be applied to meter 10.
io Outage timer 84 and outage delay timer 86 may be co~gured to avoid nuisance outages calls caused by power transients and to alter the timing of outage calls from different meters in a common outage area. Specifically, outage timer $4 may be configured to prevent calls from being made to central computer 58 until a specific amount of time has passed. In one embodiment, outage timer 84 is 1s programmed with a value between 0, indicating no delay, and 255 seconds. If the value is programmed with a non-zero value, power must be removed from meter 10 at least for that period, or valid range, of time, before microcomputer 52 proceeds.
For example, in one embodiment, diagnostic tests, or checks, are delayed a selectable period of time to allow stabilization of supplying power and meter 10. In 2o another embodiment, calls to central compute 58 are prevented until the selected period of time for stabilization has passed.
The value of outage timer 84 is altered to prevent nuisance calls from being generated from power outages having a duration iess than the programmed value of timer 84. In addition, outage delay timer 86 may be configured to prevent nuisance 25 calls from transient conditions. For example, typical outages may consist of a series of power transitions before power is completely lost and short outages may occur during normal operation due to wind blown power lines or other relatively brief disturbances. Additionally, the process of repairing local power distribution faults often produces several brief power restorations, followed by a loss of power, before power is restored permanently. In order to avoid multiple calls from being made from a plurality of meters, outage timer 84 and outage delay timer 86 may be configured to require that power be removed for a pre-defined period of time and meter 10 to have power applied for a valid range of time before an outage call is made. Specifically, if the values of both timers 84 and 86 are not within their respective valid ranges a call will not be placed to central computer 56.
Referring to Figure 7, in placing a call 236 to central computer 58, microcomputer 52 initializes 250 modem circuit 56: Initialization 250 includes configuring circuit 56 to originate a call to central computer 58, defines a phone number to call for central computer 58, and defining parameters related to the baud rate, type of handshaking and other communication parameters as known in the art.
If the outage call parameter is in a true state indicating that a call is to be made during a power outage condition, microcomputer 52 delays 252 a defined period of ~s time for outage battery 36 to reach full charge. Call delay timer 88 is started 254 and microcomputer 52 monitors 256 call delay timer 88 until the value of call timer equals the value, or valid range, defined during programming of parameters 104.
When the value of call delay timer is within the valid range, a status report is generated 258 by microcomputer 52 and a call is placed 260 to central computer 2o utilizing modem circuit 56. After the status report is generated 258, modem circuit 56 supplies the status report to telephone interface 64 and telephone line 66 so that the status report is transferred to central compute 58. If a call is completed 262, modem circuit 56 supplies 264 an outage call completed signal to microcomputer and power is removed 266 from modem circuit 56.
2s If the call is not completed, call delay timer 88 is reset and started 268.
Upon microcomputer 52 detecting 270 call delay timer 88 being within a valid range, a second call is placed 272 to central computer 58. The second call may be placed to the same phone number as described above, or may be placed to a second phone number for central computer 58. As described above, if microcomputer 52 detects 274 that the second call was completed, modem circuit 56 supplies 262 the outage call completed signal to microcomputer 52 and power is removed 264 from modem circuit 56. If the call is not completed, modem unit 50 is stopped and waits s for power to be applied to meter 10. Additional configurations may also be included, e. g. , meter 10 may attempt any number of calls and any number of different numbers prior to stopping.
In one embodiment and as shown in Figure 8, the status report generated 258 includes transferring status information, or data, from two tables stored in memory 54. Specifically, microcomputer 20 periodically executes a diagnostic, or test routine to update 300 status of meter 10. The results of the diagnostic routine is transferred from microcomputer 20 to microcomputer 52 and stored 302 in a meter status table in memory 54. A modem unit status routine is executed by microcomputer 52 to update 304 status of modem unit 50. The resulting modem 1s unit status is stored in a modem status table in memory 54. The status report generated 258 for transfer to central computer 58, includes the contents of the meter status table and the modem unit status table.
In another aspect of the present invention, in order to reduce the power consumption of outage battery 36, outage battery 36 powers only modem unit 50 2o during a power outage. Specifically, in the event of a power outage, before placing 260 call to central computer 58, microcomputer 52 updates the modem status table and stores the updated status in memory. Then, unneeded circuitry is placed in a low power sleep mode, until the outage call is placed. Once modem unit 50 is connected to central computer 58, the status report, including all required status 2s information is exchanged with to central computer 58 by transferring the meter status table and the modem status table. As a result, the time required to transmit the information is reduced which reduces power consumption of outage battery 36.
WO 00/00935 PCT/US99/145'I5 In another aspect of the present invention and in one embodiment, a statistics communication algorithm is loaded in central computer 58. Specifically, the algorithm is loaded, and stored, in a memory of central computer (not shown).
The algorithm is then executed by a microcomputer, or microprocessor (not shown) in central computer 58. The central computer microcomputer records statistical data related to the information exchanged between meter 10 and central computer 58.
The statistical data includes status information and error information. Status information is data concerning general byte counts and data packet counts.
Error information is data specifically relating the number of errors, the number of bytes 1o associated with an error, and the number of data packets associated with the errors.
At the end of exchanging information between meter 10 and central computer 58, central computer microcomputer analyzes the statistical data. If certain portions of the data meet a previously established error criteria., then the data is stored in central computer 58. The algorithm allows only data of interest to be stored thereby saving storage space and analysis time.
In another aspect of the invention, in order to prevent all meters in an outage area from calling central computer 58 at the same time, the valid range of call delay timer 88 may be unique to each meter 10. In one embodiment, a random delay is generated for each meter 10. The random delay is based on the generation of a 2o random number in a specific range from an encrypted serial number seed, or initial value. For example, in one embodiment, the valid range of call delay timer 84 is based on the unique serial number of meter I0. Using the meter serial number, microcomputer 52 generates a valid range for outage timer 84. Specifically, microcomputer 52 utilizes the encrypted serial number to generate the valid range for outage timer 84. The nature of the encryption is such that two encrypted serial numbers generated from two consecutive meter serial numbers will generate very different valid ranges for outage timer 84. As a result, meters in the outage area generate outage calls at different times. The valid range of each meter 10 may be programmed to include any valid range.
Scheduled Call Detect and Scheduled Call Scheduled call detect 126 and scheduled call 130 refer to detecting whether s the current time, as defined by real-time clock 82, is within a programmed, or pre-defined valid range. If the value of real-time clock 82 is within the valid range, the status report, as described above, is transferred to central computer 58.
Specifically, to transfer the status report, including billing information, to central computer 58, real-time clock 82 is monitored to determine whether the current time matches a value stored in memory 54. The scheduled call time value may be defined to specify a certain time, day, day of the week, day of the month, or a combination thereof. Upon detecting 126 real-time clock 88 being within the valid range, modem unit 50 initiates a call to central computer 58 as described above.
The status report, including the billing information, is then transferred to central is computer 58.
Call from Central Comy~uter and Answer Call Call from central computer 130 and Answer Call 138 refer to central computer 58 originating a call to meter 10. Specifically, and as shown in Figure 9, central computer 58 initiates a call to meter 10 utilizing telephone line 66.
Upon 2o detecting call, telephone interface supplies an incoming call signal to microcomputer 52. If a call answer parameter is detected 300 in a true, or high state, microcomputer 52 supplies a call answer signal to telephone interface 64 and modem circuit 56 so that the call is answered 302. After answering the call from central computer 58, modem circuit 56 performs handshaking 304 with central 25 computer 58 so that data may be exchanged 306 between central computer 58 and meter 10. Data continues to be exchanged 306 until the completion 308 of the exchange at which time modem circuit 56 and central computer 58 each hang up and the call is terminated.
New Program and Ueram New program 142 and update program 146 refer to transmitting a new s program to meter 10 from central computer 58, The new program is transmitted from central computer 58 to meter 10 so that the new program is stored in modem unit 50. More specifically, the new program is transferred from central computer 58 to modem unit 50 to alter operation of meter 10. For example, the new program may alter the time of the next scheduled call, the valid ranges for timer circuits 80 1o and the call answer parameters, The new program may also provide new phone numbers for calling central computer 58.
In one embodiment, the new program is stored in memory 54 including two segments. Prior to receiving the new program from central computer 58, the two segments are defined as an active segment containing the most recently programmed 1s data, or program and an inactive segment containing previously programmed data.
When a new program is received, the new program data is stored in the inactive segment. if the programming session is successfully completed, a programming complete signal is changed from the initialized low, or false state to a true, or high state. If the programming complete signal is detected to be in a high state the 2o current active segment is changed to the inactive segment and the current inactive segment is changed to the active segment.
If the programming is not completed and the programming complete signal does not transition to a high state, a loss of program call may be initiated to central computer so that the programming can be completed. When central computer 58 25 places call to meter 10, the original active and inactive segments designations will be unchanged because the new program was not successfully completed. As a result the modem unit 50 will always have a valid program, including operating parameters, so that unit 50 can continue to function properly.
Master/Slave Call end Master/Slave U~te Master/Slave Call 158 and Master/Slave Update 162 refer to placing a call to s a group of at least two meters coupled to central computer 58 utilizing a single phone line 66. Specifically and as shown in Figure 10, meters 500A, 5008, 500C, SOOD, and 500 E are coupled to central computer 58 utilizing a single telephone line 66. One meter, for example meter 500A, is designated as a master meter, while the remaining meters, 5008, 500C, 500D, and 500E are designated as slave meters.
1o Each meter includes a unique identification number, for example stored in memory 54. Information, or data, is exchanged between central computer 58 and meters 500A, 5008, SOOC, 500D, and 500E utilizing telephone line66.
Referring to Figure I1, when a phone call from central computer 58 is directed to meters 500A, 5008, 500C, 500D, and 500E utilizing phone line 66, 1s meters 500A, 5008, 500C, 500D, and 500E answer 602 call. Specifically, after master meter 500A handshakes 604 with central computer 58, meters 500A, 5008, 500C, 500D, and 500E each monitor 606 an incoming message, or data packet transferred from central computer 58. The incoming message includes an identification number that corresponds to one of meters 500A, 5008, 500C, 500D, 2o and 500E. Meters 500A, 5008, 500C, 500D, and 500E each determine 608 whether the transmitted identification number corresponds to the identification number stored in memory 54 of each meter. If the transmitted identification number matches the unique identification number stored in a meter, a transmit line of modem unit 50 of the meter matching the identification number is enabled 610 and 2s transmit lines of modem units of alI non-matching meters are disabled 612.
For example, if the identification number matches the identification number of meter 500C, the modem unit transmit lines of meters 500A, 5008, 500D, and 500E will be disabled. After information is exchanged between central computer 58 and enabled meter SOOC, meters SODA, SOOB, SOOC, 500D, and SOOE monitor 606 the next incoming message. This routine continues until central computer 58 terminates the call and hangs up.
s In addition, the master/slave configuration allows meters SOOA, SOOB, SOOC, SOOD, and SOOE to initiate a call to central computer 58 as described above using meter 10. Specifically, upon detecting a condition 106, one of meters SODA, SOOB, SOOC, SOOD, and SOOE initiates the call to central computer 58. In one embodiment, meters SOOA, 5008, 500C, 500D, and SOOE are configured so that each meter has a unique valid range for timer circuit 80 parameters and schedule time valid range. For example, to prevent meters SOOA, SOOB, SOOC, SOOD, and SOOE from originating calls without interrupting each other, meters SOOA, 5008, SOOC, SOOD, and 500E can be programmed to initiate calls only during a specific time window, e.g., meter SOOA, 10:00AM - 10:15 AM on 10/21/98, meter 5008, 15 10:16 AM - 10:30 AM on 10/22/98, SOOC, 10:45 AM - 10:59 AM on 10/22/98 SOOD, 10:16 AM - 10:30 AM on 10/23/98 and SOOE, 10:16 AM - 10:30 AM on 10/24/98. Each meter has a unique time window for originating the call to central computer 58.
Further, for events likely to occur simultaneously all meters within a the 2o group, or cluster, e.g., a power failure, meters SOOA, 5008, SOOC, SOOD, and SOOE
can be configured so that only one meter originates a call to central computer 58.
Specifically, an initiate call parameter can programmed into modem unit 50 so that microcomputer 52 is disabled from initiating call to central computer 58.
The above described modem unit exchanges information between the meter 25 and the central computer upon the occurrence of a condition within the meter. The modem unit microcomputer then evaluates the condition against parameters stored in memory 54. Using additional parameters, the microcomputer can then determine whether the information should be exchanged between the central computer and the meter. Also, the modem unit is configured to determine the proper time far exchanging the information between the central computer and the meter. Such modem unit is believed to reduce the number of nuisance type calls to central computer. Further, the modem unit is configured to allow the meter to remain operational despite error type conditions.
While the invention has been described in terms of various specific embodiments, those skilled in the art will recognize that the invention can be practiced with modification within the spirit and scope of the claims.
The algorithm is then executed by a microcomputer, or microprocessor (not shown) in central computer 58. The central computer microcomputer records statistical data related to the information exchanged between meter 10 and central computer 58.
The statistical data includes status information and error information. Status information is data concerning general byte counts and data packet counts.
Error information is data specifically relating the number of errors, the number of bytes 1o associated with an error, and the number of data packets associated with the errors.
At the end of exchanging information between meter 10 and central computer 58, central computer microcomputer analyzes the statistical data. If certain portions of the data meet a previously established error criteria., then the data is stored in central computer 58. The algorithm allows only data of interest to be stored thereby saving storage space and analysis time.
In another aspect of the invention, in order to prevent all meters in an outage area from calling central computer 58 at the same time, the valid range of call delay timer 88 may be unique to each meter 10. In one embodiment, a random delay is generated for each meter 10. The random delay is based on the generation of a 2o random number in a specific range from an encrypted serial number seed, or initial value. For example, in one embodiment, the valid range of call delay timer 84 is based on the unique serial number of meter I0. Using the meter serial number, microcomputer 52 generates a valid range for outage timer 84. Specifically, microcomputer 52 utilizes the encrypted serial number to generate the valid range for outage timer 84. The nature of the encryption is such that two encrypted serial numbers generated from two consecutive meter serial numbers will generate very different valid ranges for outage timer 84. As a result, meters in the outage area generate outage calls at different times. The valid range of each meter 10 may be programmed to include any valid range.
Scheduled Call Detect and Scheduled Call Scheduled call detect 126 and scheduled call 130 refer to detecting whether s the current time, as defined by real-time clock 82, is within a programmed, or pre-defined valid range. If the value of real-time clock 82 is within the valid range, the status report, as described above, is transferred to central computer 58.
Specifically, to transfer the status report, including billing information, to central computer 58, real-time clock 82 is monitored to determine whether the current time matches a value stored in memory 54. The scheduled call time value may be defined to specify a certain time, day, day of the week, day of the month, or a combination thereof. Upon detecting 126 real-time clock 88 being within the valid range, modem unit 50 initiates a call to central computer 58 as described above.
The status report, including the billing information, is then transferred to central is computer 58.
Call from Central Comy~uter and Answer Call Call from central computer 130 and Answer Call 138 refer to central computer 58 originating a call to meter 10. Specifically, and as shown in Figure 9, central computer 58 initiates a call to meter 10 utilizing telephone line 66.
Upon 2o detecting call, telephone interface supplies an incoming call signal to microcomputer 52. If a call answer parameter is detected 300 in a true, or high state, microcomputer 52 supplies a call answer signal to telephone interface 64 and modem circuit 56 so that the call is answered 302. After answering the call from central computer 58, modem circuit 56 performs handshaking 304 with central 25 computer 58 so that data may be exchanged 306 between central computer 58 and meter 10. Data continues to be exchanged 306 until the completion 308 of the exchange at which time modem circuit 56 and central computer 58 each hang up and the call is terminated.
New Program and Ueram New program 142 and update program 146 refer to transmitting a new s program to meter 10 from central computer 58, The new program is transmitted from central computer 58 to meter 10 so that the new program is stored in modem unit 50. More specifically, the new program is transferred from central computer 58 to modem unit 50 to alter operation of meter 10. For example, the new program may alter the time of the next scheduled call, the valid ranges for timer circuits 80 1o and the call answer parameters, The new program may also provide new phone numbers for calling central computer 58.
In one embodiment, the new program is stored in memory 54 including two segments. Prior to receiving the new program from central computer 58, the two segments are defined as an active segment containing the most recently programmed 1s data, or program and an inactive segment containing previously programmed data.
When a new program is received, the new program data is stored in the inactive segment. if the programming session is successfully completed, a programming complete signal is changed from the initialized low, or false state to a true, or high state. If the programming complete signal is detected to be in a high state the 2o current active segment is changed to the inactive segment and the current inactive segment is changed to the active segment.
If the programming is not completed and the programming complete signal does not transition to a high state, a loss of program call may be initiated to central computer so that the programming can be completed. When central computer 58 25 places call to meter 10, the original active and inactive segments designations will be unchanged because the new program was not successfully completed. As a result the modem unit 50 will always have a valid program, including operating parameters, so that unit 50 can continue to function properly.
Master/Slave Call end Master/Slave U~te Master/Slave Call 158 and Master/Slave Update 162 refer to placing a call to s a group of at least two meters coupled to central computer 58 utilizing a single phone line 66. Specifically and as shown in Figure 10, meters 500A, 5008, 500C, SOOD, and 500 E are coupled to central computer 58 utilizing a single telephone line 66. One meter, for example meter 500A, is designated as a master meter, while the remaining meters, 5008, 500C, 500D, and 500E are designated as slave meters.
1o Each meter includes a unique identification number, for example stored in memory 54. Information, or data, is exchanged between central computer 58 and meters 500A, 5008, SOOC, 500D, and 500E utilizing telephone line66.
Referring to Figure I1, when a phone call from central computer 58 is directed to meters 500A, 5008, 500C, 500D, and 500E utilizing phone line 66, 1s meters 500A, 5008, 500C, 500D, and 500E answer 602 call. Specifically, after master meter 500A handshakes 604 with central computer 58, meters 500A, 5008, 500C, 500D, and 500E each monitor 606 an incoming message, or data packet transferred from central computer 58. The incoming message includes an identification number that corresponds to one of meters 500A, 5008, 500C, 500D, 2o and 500E. Meters 500A, 5008, 500C, 500D, and 500E each determine 608 whether the transmitted identification number corresponds to the identification number stored in memory 54 of each meter. If the transmitted identification number matches the unique identification number stored in a meter, a transmit line of modem unit 50 of the meter matching the identification number is enabled 610 and 2s transmit lines of modem units of alI non-matching meters are disabled 612.
For example, if the identification number matches the identification number of meter 500C, the modem unit transmit lines of meters 500A, 5008, 500D, and 500E will be disabled. After information is exchanged between central computer 58 and enabled meter SOOC, meters SODA, SOOB, SOOC, 500D, and SOOE monitor 606 the next incoming message. This routine continues until central computer 58 terminates the call and hangs up.
s In addition, the master/slave configuration allows meters SOOA, SOOB, SOOC, SOOD, and SOOE to initiate a call to central computer 58 as described above using meter 10. Specifically, upon detecting a condition 106, one of meters SODA, SOOB, SOOC, SOOD, and SOOE initiates the call to central computer 58. In one embodiment, meters SOOA, 5008, 500C, 500D, and SOOE are configured so that each meter has a unique valid range for timer circuit 80 parameters and schedule time valid range. For example, to prevent meters SOOA, SOOB, SOOC, SOOD, and SOOE from originating calls without interrupting each other, meters SOOA, 5008, SOOC, SOOD, and 500E can be programmed to initiate calls only during a specific time window, e.g., meter SOOA, 10:00AM - 10:15 AM on 10/21/98, meter 5008, 15 10:16 AM - 10:30 AM on 10/22/98, SOOC, 10:45 AM - 10:59 AM on 10/22/98 SOOD, 10:16 AM - 10:30 AM on 10/23/98 and SOOE, 10:16 AM - 10:30 AM on 10/24/98. Each meter has a unique time window for originating the call to central computer 58.
Further, for events likely to occur simultaneously all meters within a the 2o group, or cluster, e.g., a power failure, meters SOOA, 5008, SOOC, SOOD, and SOOE
can be configured so that only one meter originates a call to central computer 58.
Specifically, an initiate call parameter can programmed into modem unit 50 so that microcomputer 52 is disabled from initiating call to central computer 58.
The above described modem unit exchanges information between the meter 25 and the central computer upon the occurrence of a condition within the meter. The modem unit microcomputer then evaluates the condition against parameters stored in memory 54. Using additional parameters, the microcomputer can then determine whether the information should be exchanged between the central computer and the meter. Also, the modem unit is configured to determine the proper time far exchanging the information between the central computer and the meter. Such modem unit is believed to reduce the number of nuisance type calls to central computer. Further, the modem unit is configured to allow the meter to remain operational despite error type conditions.
While the invention has been described in terms of various specific embodiments, those skilled in the art will recognize that the invention can be practiced with modification within the spirit and scope of the claims.
Claims (74)
1. A method of exchanging information between an electricity meter and a central computer, the meter comprising a microcomputer and a modem coupled to the central computer, said method comprising the steps of:
determining whether a condition exists in the meter; and if the condition exists, then transmitting a status report from the meter to the central computer after waiting a predefined period of time.
determining whether a condition exists in the meter; and if the condition exists, then transmitting a status report from the meter to the central computer after waiting a predefined period of time.
2. A method in accordance with Claim 1 wherein determining whether a condition exists comprises the step of determining whether at least one error, caution, and diagnostic condition exists.
3. A method in accordance with Claim 1 wherein transmitting the status report to the central computer after waiting the predefined period of time comprises the steps of:
starting an event timer;
determining whether the event timer is within a valid range;
if the event timer is within a valid range, then determining whether the condition is within a valid range; and if the condition is within the valid range, then transmitting the status report to the central computer.
starting an event timer;
determining whether the event timer is within a valid range;
if the event timer is within a valid range, then determining whether the condition is within a valid range; and if the condition is within the valid range, then transmitting the status report to the central computer.
4. A method in accordance with Claim 3 wherein transmitting the status report to the central computer comprises the steps of:
generating a status report; and transmitting the status report from the meter to the central computer utilizing the modem.
generating a status report; and transmitting the status report from the meter to the central computer utilizing the modem.
5. A method in accordance with Claim 3 wherein determining whether the event timer is within the valid range comprises the step of comparing the event timer to a delay variable.
6. A method in accordance with Claim 5 wherein comparing the event timer to the delay variable comprises the steps of:
reading a meter serial number; and generating a unique delay variable based on the meter serial number.
reading a meter serial number; and generating a unique delay variable based on the meter serial number.
7. A method in accordance with Claim 6 wherein reading the meter serial number comprises the steps of:
reading a serial number stored in the meter; and encrypting the serial number.
reading a serial number stored in the meter; and encrypting the serial number.
8. A method in accordance with Claim 3 wherein determining whether the event timer is within a valid range comprises the step of starting a delay timer.
9. A method in accordance with Claim 8 further comprising the step of:
determining whether the delay timer is within a valid range; and if the delay timer is not within the valid range, then resetting the delay timer.
determining whether the delay timer is within a valid range; and if the delay timer is not within the valid range, then resetting the delay timer.
10. A method in accordance with Claim 9 wherein the meter modem comprises a non-volatile memory and wherein said method further comprises the step if the delay timer is within the valid range, then storing the delay timer value in the non-volatile memory.
11. A method in accordance with Claim 1 wherein the meter comprises a battery for powering the meter during a power outage and the modem comprises a non-volatile memory, and wherein transmitting the status report from the meter to the central computer comprises the steps of:
applying power to the meter modem utilizing the battery; and transmitting data from tables stored in the modem memory to the central computer utilizing the meter modem.
applying power to the meter modem utilizing the battery; and transmitting data from tables stored in the modem memory to the central computer utilizing the meter modem.
12. A method in accordance with Claim 11 wherein transmitting data from the tables comprises the steps of:
reading a status from the meter microcomputer;
storing the meter status in a meter status table in the modem memory; and storing a status of the modem in a modem status table in the modem memory.
reading a status from the meter microcomputer;
storing the meter status in a meter status table in the modem memory; and storing a status of the modem in a modem status table in the modem memory.
13. A method in accordance with Claim 12 wherein transmitting data from the modem memory tables said method further comprises the step of updating the tables.
14. A method of exchanging information between an electricity meter microcomputer and a meter modem unit coupled to the meter microcomputer, wherein the meter microcomputer and the modem unit each comprise a password, said method comprising the step of:
detecting whether at least one of the meter password and the modem unit password is being changed; and if passwords being changed; then programming passwords into the meter microcomputer and the modem unit.
detecting whether at least one of the meter password and the modem unit password is being changed; and if passwords being changed; then programming passwords into the meter microcomputer and the modem unit.
15. A method in accordance with Claim 14 wherein detecting whether at least one of the meter password and the modem unit password is being changed comprises the step of supplying a disable signal from the meter microcomputer to the modem unit.
16. A method in accordance with Claim 15 wherein detecting whether at least one of the meter password and the modem unit password is being changed further comprises the step of:
detecting whether the disable signal is being supplied to the modem unit; and if the disable signal is detected at the modem unit, then disabling the modem unit password.
detecting whether the disable signal is being supplied to the modem unit; and if the disable signal is detected at the modem unit, then disabling the modem unit password.
17. A method in accordance with Claim 15 wherein programming passwords into the meter microcomputer and the modem unit comprises the steps of:
receiving the passwords from a central computer utilizing the modem unit;
storing the password in the modem unit; and storing the password in the meter microcomputer.
receiving the passwords from a central computer utilizing the modem unit;
storing the password in the modem unit; and storing the password in the meter microcomputer.
18. A method in accordance with Claim 17 wherein the modem unit comprises a non-volatile memory and wherein the storing the password in the modem unit comprises the step of storing the password in the non-volatile memory.
19. A method of exchanging information between a plurality of electricity meters and a central computer utilizing a single telephone line, the meters comprising a master meter and at least one slave meter, each meter comprising a microcomputer, a unique identifier, and a modem, said method comprising the steps of:
enabling the master meter modem to exchange information with the central computer;
transmitting information from the central computer to the meters;
determining which meter the information transmitted from the central computer is directed;
if the information transmitted is directed to the master meter, then transmitting information between the central computer and the master meter.
enabling the master meter modem to exchange information with the central computer;
transmitting information from the central computer to the meters;
determining which meter the information transmitted from the central computer is directed;
if the information transmitted is directed to the master meter, then transmitting information between the central computer and the master meter.
20. A method in accordance with Claim 19 further comprising the step if the information transmitted from the central computer is not directed to the master meter, then determining which slave meter the information is directed.
21. A method in accordance with Claim 19 wherein the information transmitted from the central computer comprises identifier data and wherein determining which slave meter the information is directed comprises the steps of:
determining whether the identifier data matches a slave meter unique identifier; and if the identifier matches a slave meter unique identifier, then disabling the master meter and enabling the slave meter whose unique identifier matches the identifier data.
determining whether the identifier data matches a slave meter unique identifier; and if the identifier matches a slave meter unique identifier, then disabling the master meter and enabling the slave meter whose unique identifier matches the identifier data.
22. A method in accordance with Claim 19 further comprising the step of transmitting a status report from the meter to the central computer.
23. A method in accordance with Claim 22 wherein transmitting a status report comprises the steps of:
determining whether a condition exists in at least one meter;
if the condition exists, then initiating a call from the meter to the central computer utilizing the meter modem.
determining whether a condition exists in at least one meter;
if the condition exists, then initiating a call from the meter to the central computer utilizing the meter modem.
24. A method in accordance with Claim 23 wherein initiating the call from the meter to the central computer comprises the step of transmitting the status report from the meter to the central computer at a predetermined time.
25. A method in accordance with Claim 24 wherein each meter has a different predetermined time to prevent interrupting another meter.
26. A method in accordance with Claim 19 wherein enabling the master meter to exchange information with the central computer comprises the step of transmitting handshaking data between the master meter and the central computer.
27. A method of programming an electricity meter comprising a microcomputer and a modem, said method comprising the steps of:
programming the meter;
determining whether the meter programming is completed; and if the meter programming is completed, then providing a programmed signal from the microcomputer to the modem.
programming the meter;
determining whether the meter programming is completed; and if the meter programming is completed, then providing a programmed signal from the microcomputer to the modem.
28. A method in accordance with Claim 27 wherein the programmed signal provided to the meter changes from a first state to a second state if the meter programming is completed.
29. A method in accordance with Claim 28 wherein if the programmed signal remains in the first state, then the meter initiates a loss of program call to a central computer.
30. A method in accordance with Claim 27 wherein the meter modem comprises a non-volatile memory having two segments and wherein programming the meter comprises the step of determining whether programming data was last stored in the first segment or the second segment of the memory.
31. A method in accordance with Claim 30 wherein if the programming data was last stored in the first segment said method comprises the step of setting a segment signal to a first state.
32. A method in accordance with Claim 31 wherein if the programming data was last stored in the second segment said method comprises the step of setting the segment signal to a second state.
33. A method in accordance with Claim 32 further comprising the step of:
determining whether the segment signal is in a first state; and if the segment signal is in the first state, then executing a program stored in the memory first segment.
determining whether the segment signal is in a first state; and if the segment signal is in the first state, then executing a program stored in the memory first segment.
34. A method in accordance with Claim 33 further comprising the step if the segment signal is in the second state, then executing a program stored in the memory second segment.
35. A method of monitoring communication errors while exchanging information between an electronic electricity meter and a computer, said method comprising the steps of:
transmitting data between the meter and the computer;
analyzing the transmitted data utilizing the computer;
determining whether the transmitted data meets an established error criteria;
and if the data meets the error criteria, then storing the data in a file in the computer.
transmitting data between the meter and the computer;
analyzing the transmitted data utilizing the computer;
determining whether the transmitted data meets an established error criteria;
and if the data meets the error criteria, then storing the data in a file in the computer.
36. A method in accordance with Claim 35 wherein analyzing the data comprises the step of tracking communicational statistical data.
37. A method in accordance with Claim 36 wherein the communication statistical data comprises status information and error information.
38. A modem unit for an electronic electricity meter for exchanging data with a central computer, the meter comprising a meter microcomputer, said unit coupled to the meter microcomputer and configured to:
determine whether a condition exists in the meter; and if the condition exists, then transmit a status report to the central computer after waiting a predefined period of time.
determine whether a condition exists in the meter; and if the condition exists, then transmit a status report to the central computer after waiting a predefined period of time.
39. A modem unit in accordance with Claim 38 wherein to determine whether a condition exists, said unit is configured to determine whether at least one error, caution, and diagnostic condition exists.
40. A modem unit in accordance with Claim 38 wherein said modem unit further comprising an event timer for measuring time, and wherein to transmit the status report to the central computer after waiting the predefined period of time, said unit is configured to:
start said event timer;
determine whether said event timer is within a valid range;
if said event timer is within a valid range, then determine whether the condition is within a valid range; and if the condition is within the valid range, then transmit the status report to the central computer.
start said event timer;
determine whether said event timer is within a valid range;
if said event timer is within a valid range, then determine whether the condition is within a valid range; and if the condition is within the valid range, then transmit the status report to the central computer.
41. A modem unit in accordance with Claim 40 wherein to transmit the status report to the central computer, said unit is configured to:
generate the status report; and transmit the status report from the meter to the central computer.
generate the status report; and transmit the status report from the meter to the central computer.
42. A modem unit in accordance with Claim 40 wherein said unit comprises a memory and wherein to determine whether said event timer is within the valid range, said unit is configured to compare the event timer to a delay variable stored in said memory.
43. A modem unit in accordance with Claim 42 wherein to compare said event timer to said delay variable, said unit is configured to:
read a meter serial number from the meter microcomputer; and generate said delay variable based on the meter serial number.
read a meter serial number from the meter microcomputer; and generate said delay variable based on the meter serial number.
44. A modem unit in accordance with Claim 43 wherein to read the meter serial number, said unit is configured to:
read a serial number stored in the meter microcomputer; and encrypt the serial number.
read a serial number stored in the meter microcomputer; and encrypt the serial number.
45. A modem unit in accordance with Claim 40 wherein said unit comprises a delay timer for measuring time and wherein to determine whether said event timer is within the valid range, said unit is configured to start said delay timer.
46. A modem unit in accordance with Claim 45 wherein said unit is further configured to:
determine whether said delay timer is within a valid range; and if the delay timer is not within the valid range, then reset said delay timer.
determine whether said delay timer is within a valid range; and if the delay timer is not within the valid range, then reset said delay timer.
47. A modem unit in accordance with Claim 46 wherein said modem unit comprises a non-volatile memory and wherein if said delay timer is within the valid range, then store a value of said delay timer in said non-volatile memory.
48. A modem unit in accordance with Claim 38 wherein the meter further comprises a power outage battery and said unit comprises a non-volatile memory, and wherein to transmit the status report from the meter to the central computer, said unit is configured to:
receive power from said battery; and transmit data from tables stored in said modem memory to the central computer.
receive power from said battery; and transmit data from tables stored in said modem memory to the central computer.
49. A modem unit in accordance with Claim 48 wherein to transmit data from the memory tables said unit is further configured to:
read a status from said meter microcomputer;
store the meter status in a meter status table in said modem unit memory;
and store a modem unit status a modem status table in said modem unit memory.
read a status from said meter microcomputer;
store the meter status in a meter status table in said modem unit memory;
and store a modem unit status a modem status table in said modem unit memory.
50. A method in accordance with Claim 48 wherein said modem unit is further configured to update said modem unit memory tables before the data is transmitted from said modem unit memory tables.
51. An electricity meter comprising a microcomputer and a modem unit, said modem unit and said microcomputer each having a password, said meter configured to:
determine whether at least one of said meter microcomputer password and said modem unit password is changed; and if changed; then program passwords into said meter microcomputer and said modem unit.
determine whether at least one of said meter microcomputer password and said modem unit password is changed; and if changed; then program passwords into said meter microcomputer and said modem unit.
52. A meter in accordance with Claim 51 wherein to determine whether at least one of said meter microcomputer password and said modem unit password is changed, said meter is configured to supply a disable signal from said microcomputer to said modem unit.
53. A meter in accordance with Claim 52 wherein to determine whether at least one of said meter microcomputer password and said modem unit password is changed, said meter is further configured to:
detect whether said disable signal is being supplied to said modem unit; and if said disable signal is detected at said modem unit, then disable said modem unit password.
detect whether said disable signal is being supplied to said modem unit; and if said disable signal is detected at said modem unit, then disable said modem unit password.
54. A meter in accordance with Claim 52 wherein to program passwords into said meter microcomputer and said modem unit, said meter is configured to:
receive a password from a central computer via said modem unit;
store said password in said modem unit; and store said password in said meter microcomputer.
receive a password from a central computer via said modem unit;
store said password in said modem unit; and store said password in said meter microcomputer.
55. A meter in accordance with Claim 54 wherein said modem unit comprises a non-volatile memory and wherein to store said password in said modem unit, said meter is configured to store said password in said modem unit non-volatile memory.
56. A system for exchanging information with a central computer utilizing a single telephone line, said system comprising a plurality of meters each comprising a microcomputer, a unique identifier, and a modem board, said system configured to:
designate one of said meters as a master meter;
designate remaining said meters as slave meters;
enable said master meter modem;
transmit information from the central computer to said meters;
determine which of said meters the information transmitted from the central computer is directed;
if the information transmitted is directed to the master meter, then transmit information between the central computer and said master meter.
designate one of said meters as a master meter;
designate remaining said meters as slave meters;
enable said master meter modem;
transmit information from the central computer to said meters;
determine which of said meters the information transmitted from the central computer is directed;
if the information transmitted is directed to the master meter, then transmit information between the central computer and said master meter.
57. A system in accordance with Claim 56 further configured to determine which of said slave meters the information is directed, if the information transmitted from the central computer is not directed to said master meter.
58. A system in accordance with Claim 56 wherein the information transmitted from the central computer comprises identifier data and wherein to determine which of said slave meters the information is directed, said system is configured to:
determine whether said identifier data matches one of said slave meter unique identifiers; and if said identifier matches a slave meter unique identifier, then disable said master meter and enabling said slave meter whose unique identifier matches said identifier data.
determine whether said identifier data matches one of said slave meter unique identifiers; and if said identifier matches a slave meter unique identifier, then disable said master meter and enabling said slave meter whose unique identifier matches said identifier data.
59. A system in accordance with Claim 56 further configured to transmit a status report from said meter to the central computer.
60. A system in accordance with Claim 59 wherein to transmit the status report, said system is configured to:
determine whether a condition exists in at least one meter;
if the condition exists, then initiate a call from said meter to the central computer to transmit the status report.
determine whether a condition exists in at least one meter;
if the condition exists, then initiate a call from said meter to the central computer to transmit the status report.
61. A system in accordance with Claim 60 wherein to initiate the call from said meter to the central computer, said system is configured to transmit said status report from said meter to the central computer at a predetermined time.
62. A system in accordance with Claim 61 wherein each of said meters comprise a unique predetermined time to prevent interrupting another of said meters.
63. A system in accordance with Claim 60 wherein to initiate a call from said meter to the central computer, said system is configured to initiate a call from said master meter to the central computer.
64. A programmable electronic electricity meter comprising a microcomputer and a modem coupled to a central computer, said meter configured to:
receive programming data from the central computer utilizing said modem to program the meter;
determine whether said meter programming is completed; and if the meter programming is completed, then provide a programmed signal from said modem to said microcomputer.
receive programming data from the central computer utilizing said modem to program the meter;
determine whether said meter programming is completed; and if the meter programming is completed, then provide a programmed signal from said modem to said microcomputer.
65. A meter in accordance with Claim 64 wherein said programmed signal provided to said modem changes from a first state to a second state if said meter programming is completed.
66. A meter in accordance with Claim 65 wherein if the programmed signal remains in the first state, then said meter initiates a loss of program call to a central computer.
67. A meter in accordance with Claim 61 wherein said meter modem comprises a non-volatile memory having at least two segments and wherein to program said meter, said meter is configured to determine whether programming data was last stored in a first segment or a second segment of said modem memory.
68. A meter in accordance with Claim 67 wherein said meter is configured to set a segment signal to a first state if the programming data was last stored in said first segment.
69. A meter in accordance with Claim 68 wherein said meter is configured to set said segment signal to a second state if the programming data was last stored in said second segment.
70. A meter in accordance with Claim 69 further configured to:
determine whether said segment signal is in said first state; and if the segment signal is in said first state, then execute a program stored in said memory first segment.
determine whether said segment signal is in said first state; and if the segment signal is in said first state, then execute a program stored in said memory first segment.
71. A meter in accordance with Claim 70 further configured to execute a program stored in said memory if said segment signal is in said second state.
72. A system for monitoring communication errors while exchanging data between an electronic electricity meter and a computer, said system configured to:
transmit data between the meter and the computer;
analyze the transmitted data utilizing the computer;
determine whether the transmitted data meets an established error criteria;
and if the transmitted data meets said error criteria, then storing the data in a file in the computer.
transmit data between the meter and the computer;
analyze the transmitted data utilizing the computer;
determine whether the transmitted data meets an established error criteria;
and if the transmitted data meets said error criteria, then storing the data in a file in the computer.
73. A system in accordance with Claim 72 wherein to analyze the transmitted data said system is configured to track communicational statistical data.
74. A system in accordance with Claim 73 wherein said communication statistical data comprises status information and error information.
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US9103998P | 1998-06-29 | 1998-06-29 | |
US60/091,039 | 1998-06-29 | ||
PCT/US1999/014575 WO2000000935A1 (en) | 1998-06-29 | 1999-06-28 | Electronic electricity meter |
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CA2301700C CA2301700C (en) | 2013-06-25 |
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CN (1) | CN100388320C (en) |
AU (1) | AU4838399A (en) |
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CN106124851A (en) * | 2016-06-13 | 2016-11-16 | 罗文凤 | A kind of control method for intelligent electric meter |
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DE102007017985A1 (en) * | 2007-04-07 | 2008-10-09 | EnBW Energie Baden-Württemberg AG | A supply media amount detection system and method of operating a utility volume detection system |
CN111063183B (en) * | 2019-12-25 | 2021-03-19 | 宁波三星医疗电气股份有限公司 | Bluetooth-based electric energy meter statistical method and device and storage medium |
CN112793420B (en) * | 2021-01-15 | 2022-07-19 | 东风柳州汽车有限公司 | Vehicle combination instrument initialization method, device, equipment and storage medium |
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US4697182A (en) * | 1985-09-16 | 1987-09-29 | Sangamo Weston, Inc. | Method of and system for accumulating verifiable energy demand data from remote electricity meters |
US5309363A (en) * | 1992-03-05 | 1994-05-03 | Frank M. Graves | Remotely rechargeable postage meter |
US5469365A (en) * | 1993-01-25 | 1995-11-21 | Customs Ideas | Power monitor unit |
US5606507A (en) * | 1994-01-03 | 1997-02-25 | E-Stamp Corporation | System and method for storing, retrieving and automatically printing postage on mail |
DE4447404C2 (en) * | 1994-12-23 | 1998-08-20 | Francotyp Postalia Gmbh | Method for entering data into a balance and arrangement for carrying out the method |
US5742512A (en) * | 1995-11-30 | 1998-04-21 | General Electric Company | Electronic electricity meters |
KR100415504B1 (en) * | 1996-05-17 | 2004-05-12 | 삼성전자주식회사 | Computer system installing automatic response device and its operating method for automatic response in hibernation state |
CN1225186A (en) * | 1996-12-18 | 1999-08-04 | 亚历山大S·奥伦斯坦 | Secured system for accessing application services from a remote station |
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- 1999-06-28 EP EP99931978A patent/EP1040453A4/en not_active Ceased
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- 1999-06-28 AU AU48383/99A patent/AU4838399A/en not_active Abandoned
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- 1999-06-28 CN CNB998010464A patent/CN100388320C/en not_active Expired - Fee Related
Cited By (1)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN106124851A (en) * | 2016-06-13 | 2016-11-16 | 罗文凤 | A kind of control method for intelligent electric meter |
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EP1040453A1 (en) | 2000-10-04 |
EP1040453A4 (en) | 2001-05-02 |
AU4838399A (en) | 2000-01-17 |
WO2000000935A1 (en) | 2000-01-06 |
BR9906588B1 (en) | 2014-10-21 |
CN1273659A (en) | 2000-11-15 |
WO2000000935A9 (en) | 2000-10-26 |
BR9906588A (en) | 2000-07-18 |
CN100388320C (en) | 2008-05-14 |
CA2301700C (en) | 2013-06-25 |
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