Abstract:
A utility meter comprises an electromechanical metering portion connectable to a power drop to a premises and an electronic portion coupled to the electromechanical portion. The electromechanical portion comprises a rotating disk portion rotating at speeds proportional to power flow through said meter. The electronic portion comprises an interface coupled to the rotating disk, a controller coupled to the interface for accumulating power usage data over predetermined intervals, a memory coupled to the controller for storing power usage data, and a modem interface for coupling the controller to a public network. The controller is programmably operative to automatically establish a connection via the modem interface for uploading power usage data stored in the memory.

Description:
FIELD OF THE INVENTION  
         [0001]    This invention pertains to utility company meters and systems for metering electrical energy, in general, and to single phase residential type watt-hour meters and systems and methods for the measurement of electrical energy consumption for revenue metering and for other energy consumption applications, in particular.  
         BACKGROUND OF THE INVENTION  
         [0002]    Typically, electrical power supplied for residential applications is single phase alternating current power. To measure the consumption of electricity in residential applications, a utility company meter is provided at the electrical service entrance to the residence. Utility company meters are of three general types, namely, electromechanical based meters, purely electronic component based meters, and hybrid electromechanical/electronic meters. The electromechanical and hybrid type meters are essentially an induction motor in which the moving element is a rotating disk. The speed of rotation of the disk is directly proportional to the voltage applied and the amount of current flowing through the motor. The phase displacement of the current, as well as the magnitude of the current, is automatically taken into account by the meter, i.e., the power factor influences the speed of rotation of the disk. The result is that the disk rotates with a speed proportional to true power. In the electromechanical type of meters, a register is used to register the number of revolutions, and the gearing is arranged to be read directly in kilowatt-hours.  
           [0003]    The electric utility meters most commonly in use are of the electromechanical type. The meters are generally highly reliable, but do not lend themselves to remote or automated reading.  
           [0004]    Hybrid meters typically utilize electronic circuitry in combination with the rotating disk to permit at least limited two-way communication to/from the meter. Typically, the two-way communication is limited to reading the meter via a proprietary communications link that frequently is a limited range radio frequency link.  
           [0005]    It is not uncommon for electric utilities to utilize both simple and complex tariffs. The tariffs may be time of use type tariffs, or may be changed from time to time or on predetermined dates to provide for various time of use type of rates.  
           [0006]    It is common practice for utility companies to access meter information on only a monthly or 30 day period.  
           [0007]    In addition, present metering technology makes it inconvenient for a consumer to determine in a timely fashion the amount of energy being consumed.  
         SUMMARY OF THE INVENTION  
         [0008]    The present invention provides the next generation of time-sensitive advanced metering data collection and management solutions for utilities and energy service providers. The meter and system of the invention provide unmatched two-way, secure internet-based access to real-time usage information between data networks and control systems.  
           [0009]    The system measures residential energy consumption and automatically communicates this information to a host computer. The host computer can then be accessed by the end utility customer or other authorized entities. This Internet or web based system offers two-way communication capability to support meter reconfiguration. The system is comprised of two major elements, a hardware unit and database software.  
           [0010]    In accordance with one aspect of the invention, the hardware unit is a printed circuit type card that retrofits into form 2S single-phase residential-type meters. The unit measures residential energy consumption in predefined intervals, stores the measurements, and communicates at predefined times to a host database server. The unit can accommodate various wired or wireless communication technologies through a simple communications port.  
           [0011]    In accordance with another aspect of the invention, the database software resides at a server and provides for storage, configuration and analysis of energy usage data that is transmitted from the hardware unit. The database maintains the usage information in a summarized form and provides real time analysis of the data via open and secure API&#39;s (application protocol interfaces). The database can be accessed over the Internet to access and extract data files. The output format of the database can readily be configured to integrate to a utility company&#39;s computer system and database.  
           [0012]    Electric usage meters in accordance with the invention, capture and transmit energy-use information in configurable time intervals directly to a data center via public networks. Each meter in accordance with the principles of the invention includes built-in measurement and state-of-the-art data communications systems that provide high- volume, real-time energy-use monitoring over the Internet to a server and database. By utilizing the Internet, cost-effective reliable intelligent meter modules, existing public network infrastructure, and sophisticated head-end database management systems, a system in accordance with the principles of the invention offers unparalleled practical, flexible, metering modernization solutions to electric utilities customers. The system of the present invention eliminates the need to deploy costly, complex, and often high- maintenance private communications networks to capture periodic utility data. Standard Internet browser technology and encrypted messaging provide secure, easy accessibility to metered data. The meters and system provide the ability to capture, analyze and consistently deliver accurate and timely electric-use consumption data is critical to the future growth of electricity providers everywhere.  
           [0013]    A utility meter in accordance with the principles of the invention comprises an electromechanical metering portion connectable to a power drop to a premises and an electronic portion coupled to the electromechanical portion. The electromechanical portion comprises a rotating disk portion rotating at speeds proportional to power flow through said meter. The electronic portion comprises an interface coupled to the rotating disk, a controller coupled to the interface for accumulating power usage data over predetermined intervals, a memory coupled to the controller for storing power usage data, and a modem interface for coupling the controller to a public network. The controller is programmably operative to automatically establish a connection via the modem interface for uploading power usage data stored in the memory.  
           [0014]    Power usage data is accumulated and stored incrementally for automatic transmission. In the illustrative embodiment of the invention, power usage data is acquired from meters in 15-minute increments instead of the monthly or 30-day time frame presently used. As a result, utilities can better predict and manage electricity use. The meter of the invention gives great latitude to utilities to select a deployment strategy best suited to their unique needs. There is no implicit requirement for mass installation of geographic metering territories as with some systems. Thus, utilities with strategies for “surgical” implementation of AMR are easily accommodated.  
           [0015]    In accordance with the principles of the invention a remotely configurable meter includes a unique physical meter number and is provided with a unique electronic serial number.  
           [0016]    The meter includes memory for storing rate schedule information and for storing consumption information based upon the rate schedule information.  
           [0017]    In accordance with another aspect of the invention, the meter utilizes a public network for the communication link. In one embodiment of the invention, the public network comprises a worldwide network of computers. The public network in the embodiment shown comprises the Internet and the communications link includes a telephone link. The telephone link comprises one or more of a wired telephone line, a wireless telephone line, a radio frequency communications link, and an optical link.  
           [0018]    In the illustrative embodiment of the invention the rate schedule information may be a time of use plan or a flat rate plan. Downloading of predetermined intervals from the database to the meter as part of the configuration information is used by a the meter to calculate usage.  
           [0019]    In accordance with another aspect of the invention an optical communications link is provided at the electric utility meter. A handheld device is utilized to download configuration information to the electric utility meter via the optical link. The handheld device in the illustrative embodiment may be selected from one of a personal digital assistant or a computer.  
           [0020]    The configuration information may include a premises identification code downloaded from the handheld device to the electric utility meter via the optical link.  
           [0021]    The information may also include Internet service provider information including at least one telephone number to access a server via a communications link. The information may further include a username and password.  
           [0022]    In accordance with an aspect of the invention the handheld device is used to control the meter such that the electric utility meter initiates a connection via a public network communications link to a server and to causes the meter to upload stored data to the server.  
           [0023]    In accordance with another aspect of the invention the handheld device utilizes the optical link to perform field diagnostic functions.  
           [0024]    Still further in accordance with the invention the meter responds to the handheld device to establish a TCP/IP connection to a server via a communications link over a public network. 
       
    
    
     BRIEF DESCRIPTION OF THE DRAWING  
       [0025]    The invention will be better understood from a reading of the following detailed description in conjunction with the drawing figures in which like reference numerals are used to designate like elements, and in which:  
         [0026]    [0026]FIG. 1 is a block diagram of a meter reading and control system in accordance with the principles of the invention;  
         [0027]    [0027]FIG. 2 is a block diagram of a power meter in accordance with the principles of the invention;  
         [0028]    [0028]FIGS. 3 and 4 are flow charts illustrating a method of remotely configuring individual power meters in accordance with the principles of the invention;  
         [0029]    [0029]FIGS. 5, 6, and  7  are tables of functions provided in accordance with the invention; and  
         [0030]    [0030]FIG. 8 illustrates a rotating disk in accordance with the principles of the invention. 
     
    
     DETAILED DESCRIPTION  
       [0031]    Each utility meter is required to record the electricity consumption at a particular premises. With the advanced metering provided by a time of use meter in accordance with the principles of the invention, it is possible to support a number of different pricing plans. These plans vary the cost of electricity of the consumer according to the time of day and/or maximum load that the consumer draws from the utility grid. The meter and system described here allows a utility company to remotely control the schedule programming of individual meters from a central computer. All information relating to calendars, daily schedules (On peak, Off peak, shoulder  1  and shoulder  2  rate time intervals) and seasonal information is downloaded annually from the database server or whenever there is a change required (such as a rate change or if a customer changes from a flat rate kWh plan to a Time of Use plan)  
         [0032]    In accordance with the principles of the invention, a new and novel utility meter is provided and a new and novel system and method for acquiring metered information is provided. The system in which the meters may be utilized is shown in FIG. 1. The system is designated generally at  100 . System  100  includes a server  101 . Server  101  is coupled to a data center  103  that includes relational databases in which utility meter acquired data and account information is stored. System  100  is coupled via a firewall  105  to a computer network that in the embodiment shown is the Internet  111  that has access to utility meters  113 . System  100  also is accessible via protective firewalls  107  by the utility company&#39;s virtual private network  109 . Bi-directional communication occurs between each utility meter  113  and system  100  via point of presence (POP)  115 . In addition, Internet communication devices such as personal computer  117  may access meters  113  and system  100 .  
         [0033]    The hardware design is comprised of a controller with program memory, a liquid crystal display to replace the mechanical registers of the retrofitted meter; direction sensing infra-red disk interface, irDA communications port for diagnostics; non-volatile memory for interval reading storage; a real-time clock for time stamping of data measurements and a serial port to interface with various wired or wireless communication modules. The unit features Time of Use (TOU) demand metering as well as flat rate metering; records usage in predefined intervals, such as 15, 30, or 60 minutes, or other interval; stores up to 31 days of 15 minute interval data; is programmable to send information to host computer daily; power failure detection; backward rotation detection. The unit can access dual ISP&#39;s to enhance communication reliability through redundancy. The meter software establishes an Internet connection to the portal server that, in turn, executes a set of procedures to validate each transaction from the meter to the database server before inserting packet data into the database server. Data integrity and duplication checks are performed in the validation process. The software manages field upgrades through the Internet; offers event notification of hardware failure, power up, power outage and tamper/theft detection with notification capabilities; offers diagnostics of event, connect and diagnostics logs.  
         [0034]    Included with this system is a basic set of energy consumption reporting software. These reports offer monthly and daily usage in the presentation format of tabular, bar or pie charts.  
         [0035]    Each utility meter  113  is capable of measuring energy consumption in real time. Electrical usage readings are taken at programmed predetermined intervals and are stored in a non-volatile memory at the utility meter. Each meter  113  periodically establishes a link to system  100 . In the illustrative embodiment of the invention, the link is via the public telecommunications network. Each meter  113  includes a modem that, in this embodiment of the invention, is controlled to establish a link via the telephone lines at the residence where the utility meter is installed. Meter  113  includes an auto dialer that is under software control at the respective meter  113  to dialup a connection via Internet  111  to system  100  to upload power usage data from meter  113  to system  100  for storage in data center  103 .  
         [0036]    As noted above, each utility meter  113  takes electricity usage data in predetermined intervals that are determined by embedded software in the meter  113 . The predetermined intervals may be pre-selected at 5, 10, 15, 30, or 60 minutes. The usage is calculated in accordance with predetermined quantifications or “buckets” of total power consumed, power consumed in peak times, power consumed in off-peak times; and power consumed during peak/off-peak shoulder periods. To reduce interference with telephone usage at the residence where the meter is installed, and to take advantage of lower priced night rates, meter  113  communicates to system  100  during night hours of 12 pm to 5 am.  
         [0037]    In the illustrative embodiment of the invention, each utility meter  113  is a hybrid electromechanical/electronic meter. The electromechanical portion includes the rotating disk that operates as an induction type squirrel cage motor as described above. The register portion of the meter is replaced with a programmable structure. The programmable structure  200  of a meter  113  in accordance with the principles of the invention is shown in FIG. 2.  
         [0038]    The illustrative embodiment comprises a printed circuit board or structure  200  that is added to a conventional single-phase electromechanical meter. Printed circuit board  200  carries the components that are represented in the block diagram of FIG. 2.  
         [0039]    Structure  200  includes a power supply  207 . Power supply  207  provides direct current power to the various components of structure  200 . Power supply  207  includes a rectifier  209  coupled to a first voltage regulator  211  that provides a 5 volt d.c. output. First regulator  211  is coupled to a “super” capacitor  213 . Super capacitor  213  comprises two 4.7 Farad capacitors. Super capacitor  213  is provided to provide for uninterrupted power to structure  200  for a period of time should there be brief power outages. The voltage output of super capacitor  213  is coupled to a second voltage regulator  215 . Second voltage regulator  215  is a 3.6 volt regulator that provides power to the remainder of the circuits of structure  200 . An under voltage circuit  217  is coupled to the output of second voltage regulator  215 . In the event that the voltage output of second voltage regulator  215  falls to a predetermined voltage level, a trigger signal is generated that is utilized to trigger a reset function.  
         [0040]    Structure  200  includes a controller  201 . Controller  201  is a commercially available microprocessor. A real time clock controller  203  is controlled by a crystal oscillator is coupled to controller  201  to provide clocking for operation of controller  201 . A non-volatile electrically modifiable memory NVM  205  (EEPROM, FRAM or other commercially available memory) is coupled to processor  201 .  
         [0041]    An optical disk interface  219  is coupled to controller  201  and to the rotating disk of utility meter  113 . Optical disk interface  219  is optically coupled to the rotating disk and generates signals to CPU  219  to indicate power consumption.  
         [0042]    Structure  200  includes an onboard silicon serial number chip  227 . Silicon serial number  227  is a commercially available product. Each chip is a unique, factory-lasered and tested 64-bit registration number that includes an 8 bit family code, plus a 48-bit serial number plus an 8-bit CRC tester. No two parts are alike. One such product is the DS2401 available from Dallas Semiconductor  
         [0043]    Structure  200  further includes an optical communication or infrared data access interface  225 . IrDA interface  225  is capable of communicating with a handheld device.  
         [0044]    Structure  200  also includes a wide area network interface  223  that provides one or more of analog modem functionality, cellular telephone modem functionality, satellite communication functionality, 2 way paging functionality, or power line carrier functionality.  
         [0045]    In addition, structure  200  includes a display module and display driver  229  coupled to controller  201 . The display module is utilized to provide an electronically generated human readable output of energy consumption. In another embodiment of the invention, display and driver  229  may be mounted separate from meter  113 . For example, display and driver  229  may be mounted inside the customer&#39;s premises rather than at meter  113  to thereby permit the customer to more easily see power consumption. By providing a display that is readable within the serviced premises, the owner of the premises may be better able to manage and reduce power consumption.  
         [0046]    In yet another embodiment of the invention, meter  113  may be coupled to display driver  229  via wireless or wired technology.  
         [0047]    Each printed circuit board  200  and its associated utility meter  113  is uniquely identified by the silicon serial number  227 . In addition, each utility meter  113  has an identification number that is assigned to it that is unique to the utility providing service. The identification number is displayed on a nameplate on meter  113  and is displayed in alphanumeric form as well as in a bar code format. During the final stage of manufacturing of utility meters  113 , meter identification number and the corresponding silicon serial number are transmitted to data center  103  and stored in the database.  
         [0048]    The bar code on the meter  113  is scanned into a handheld device and subsequently beams the identification number via IrDA interface  225  to controller  201 . Controller  201  stores the identification number in memory. On a command from the operator, controller  201  utilizes modem interface  223  to contact database server  101  to transmit the identification number and silicon serial number to database  103  so that the correlation between the identification number and the silicon serial number may be recorded.  
         [0049]    Data center  103  must store information pertaining to rate schedules for each individual service residence/account. By way of example, the rate schedules may be flat rate or time of use. If the rate schedule is time of use, then the rate schedule to be implemented is also associated with the individual service residence/account.  
         [0050]    When an installer installs a meter  113  at a customers premises the following steps as shown in FIG. 3 occur. At step  301  the meter is powered up. Upon power up, the meter goes through an initialization and self-test process. The initialization and self-test is performed in accordance with software stored in NVM  205 . Upon completion of the initialization and self-test, controller  201  utilizes modem  223  to establish a TCP/IP connection with server  101  and sends a message to server  101  that it is powered up at step  303 . Server  101  receives the power up indication. Server  101  sends an acknowledgement signal back to controller  201  and also transmits the current time to controller  201 . At step  305 , controller  201  receives the time indication from server  101  and utilizes the time indication to set its internal clock. In addition, controller  201  sends an acknowledgment signal back to server  101 .  
         [0051]    The meter installer has an installation route sheet that identifies each service premises that is having a meter installed with a premise identification number. The premise identification number is bar coded. The installer at step  307  scans the bar coded premise identification with his or her handheld unit. The handheld unit is then used to transmit the premises identification to controller  201  via IrDA interface  225  at step  307 . Controller  201  stores the premises identification in NVM  205  and transmits the silicon serial number and premise identification number to server  101  at step  309 . Server  101  causes the premise identification number to be associated with the silicon serial number in data center  103 . At step  310  server  101  detects that the information is provided as a result of a new field installation and utilizes the premise identification number to retrieve schedule and rate information from data center  103  and transmit the schedule and rate information to meter  113  at step  311 .  
         [0052]    The rate information includes an indication of whether the rate is a flat rate or time of use rate structure. If the rate is a time of use structure, then calendar information is sent. The calendar information may include season information and a list of holidays. In addition, for each season, the rate information may include a weekday schedule, a Saturday schedule, a Sunday schedule and a Holiday schedule. If the rate schedule is a flat rate, then a flat rate configuration is sent to meter  113  that includes no calendars and that the power usage is to be accumulated as a total accumulation. Meter  113  receives the rate information at step  313  and stores it internally in NVM  205  at step  315 . The rate schedule is effected immediately upon receipt.  
         [0053]    Turning back to FIG. 2, controller  201  communicates to server  101  via modem  223 . Modem  223  may operate with any of the cellular telephone system formats that are deployed including GSM or CDMA and including packet or not. In addition, modem  223  is capable of making a direct connection with a remote TCP/IP address as follows as shown in the flow chart of FIG. 4  
         [0054]    At step  401 , controller  201  determines that it needs to connect to data center  103  via server  101  The determination is made either as a result of a regular programmed event such as a daily upload, or for a special event such as a loss of power.  
         [0055]    Controller  201  utilizes modem  223  to establish a TCP/IP connection at step  403  to server  101 . Sever  101  immediately provides an acknowledgment of the connection at step  405 . Controller  201  via modem  223  sends a message to server  101  along with appropriate data message at step  407 . Server  101  acknowledges receipt of the data message at step  409 . Checksum error detection is utilized. In the event that an acknowledgement is not received, controller  201  causes the message to be resent as indicated at step  411 . The resend feature may be repeated for a predetermined number of times if an acknowledgment is not received.  
         [0056]    As briefly described above in conjunction with FIG. 1, a handheld unit  150  may be used in conjunction with meter  113 . Handheld unit  150  may be a commercially available PDA or a personal computer. The hand held unit includes software that permits it to provide the user with certain functionality. As shown in FIG. 2, the illustrative embodiment shows an IrDA interface  225  to permit infrared communication between handheld unit  150  and controller  201 . The communications between handheld unit  150  and meter  113  may be classified by function as useful functions, field programming functions and field diagnostic functions.  
         [0057]    One particular advantage of the meter of the invention is that the IrDA port and interface permits the use of readily available handheld devices such as Personal Digital Assistants (PDA) or computer with an infrared output or any other programmable device having an infrared communication port. PDA&#39;s that may be used are any of those that are commercially available such as the Palm Pilot. In the description that follows, it should be understood that references to PDA include not only commercially available PDAs, but may also include any other portable or handheld computer device.  
         [0058]    A properly programmed PDA or computer device  150  may be used to communicate with a meter  113  as shown in FIG. 1. The PDA  150  is carried to a physical proximity of meter  113 . PDA  150  utilizes a bar code reader to scan the premise identification bar code and the meter bar code. PDA  150  is used to locally access meter  113  to make fault logs for meters; to force a meter  113  into a communication mode with server  101  and to read the meter. Each PDA  150  includes security in that PDA&#39;s are periodically programmed with a password that is verified during access to a meter from server  101 . In the event that a password is invalid or expired, communication to server  101  from PDA  150  is blocked.  
         [0059]    The useful type of functions includes using handheld unit  150  to set the date and time in meter  113 . Handheld unit  150  may also be used to force controller  201  to initiate a connection to server  101  to send all available stored data from meter  113  to server  101 , or to force controller  201  to send all previously unset data to server  101 . In addition, handheld unit  150  may be used to cause controller  201  to send a power up message to server  101 . These field functionalities are listed in Table 1 shown in FIG. 5  
         [0060]    Handheld unit  150  may be used to set up configuration of controller  201  by providing the premises identification code to controller  201 . In addition, as part of the configuration set up, handheld unit  150  may set Internet Service provider information in controller  201  including a username, password and one or more phone numbers for dial up.  
         [0061]    The field programming functions that handheld unit  150  provides may be loaded in a single message for controller  201 . These field-programming functions are listed in Table 2 of FIG. 6.  
         [0062]    In addition to the above functionality provided, handheld unit  150  can provide field diagnostic functionality to cause controller  201  to display a connect log indicating connections made to server  101 . In addition, handheld unit  150  can cause controller  201  to display the states of various information stored in controller  201  memories and NVM  205 . The diagnostic information that is obtainable via handheld unit  150  is shown in Table 3 of FIG. 7.  
         [0063]    In instances that handheld unit  150  initiates communications between controller  201  and server  101 , handheld unit  150  will also transmit a password to controller  201 . The password will be sent to server  101  for verification. In the event that the password fails verification, command information sent to server  101  will not be acted on. The password is loaded into handheld unit  150  and is valid for a predetermined time period after which it must be replaced.  
         [0064]    A significant aspect of the present invention is the manner in which usage data is acquired from the rotating disk of the meter. As shown in FIGS. 8 and 9, rotating disk  601  includes a matte black stripe  603  painted on it. The stripe  603  covers approximately 5 to 10% of the one surface  605  of disk  601 . The IrDA interface includes two opto-coupler pairs  607 ,  609 , each comprising an infrared emitter  611  and a phototransistor  613  that are positioned proximate disk  601 . The two opto pairs  607 ,  609  are spaced apart by less than the width of the black stripe  601 . The infrared emitters  611  are both pulsed at the same time. Each infrared emitter  611  is pulsed on for approximately 500 microseconds every 5 milliseconds. The output of each phototransistor  613  is coupled to an analog to digital converter that is on controller  201 . The outputs of the two opto pairs  607 ,  609  are sampled while the infrared emitters are pulsed but after a brief settling period. Controller  201  operates in accordance with a program that determines whether each opto pair  607 ,  609  is proximate the dark stripe  603  on disk  601  or not. When an opto pair  607 ,  609  is proximate stripe  603 , the corresponding phototransistor  613  is “off”. When the opto pair  607 ,  609  is proximate the non-black portions of disk  601 , disk  601  reflects the infrared light from emitter  611  back to the corresponding phototransistor  613  of the pair and the phototransistor  613  is “on”. The software program operates as a state machine.  
         [0065]    If disk  601  is rotating forwards, which is the correct direction for power consumption, then the normal sequence of events for the two opto pairs  607 ,  609  is as set forth in Table 1.  
                           TABLE 1                                       a.   Opto 1 on, Opto 2, off           b.   Opto 1 off (black region), Opto 2 on           c.   Opto 1 off, Opto 2 off           d.   Opto 1 on, Opto 2 off           e.   Opto 1 on, Opto 2 on                      
 
         [0066]    If disk  601  is rotating backwards, then the sequence of events will be as set forth in Table 2.  
                           TABLE 2                                       a.   Opto 1 on, Opto 2, on           b.   Opto 1 on, Opto 2 off           c.   Opto 1 off, Opto 2 off           d.   Opto 1 off, Opto 2 on           e.   Opto 1 on, Opto 2 on                      
 
         [0067]    By tracking the sequences of states of the outputs of the opto transistors  607 ,  609 , controller  201  determines whether the direction of rotation is forward or backward. Only these two state sequences will occur if the meter  113  is operating properly. Each time controller  201  identifies the occurrence of one of the two state sequences and each time a predetermined state transition occurs, controller  201  will record one revolution. Assuming that controller  201  detects the first state sequence as shown in Table 1, controller  201  records the revolution as being in a first or forward direction when it detects the state transition from state d. to state e. in Table 1. If controller  201  detects the second state sequence as shown in Table 2, controller  201  records the revolution as being in the second or backward direction when it detects the state transition from state d. to state e. in Table 2.  
         [0068]    In operation, controller  201  accumulates the number of revolutions of disk  601  without accounting for whether the rotation is in the forward or reverse direction. In the illustrative embodiment of the invention, each meter  113  is configured as a form 2S type meter. Form 2S is such that the electrical contacts to the power grid and to the served premises are symmetrically configured. Because of the symmetrical configuration, it is possible for the meter to be mounted in the housing upside down. When the meter  113  is placed in the housing upside down, the rotating disk  601  will rotate in the reverse direction. When rotating disk  601  runs backwards, the register is run backwards in conventional meters. More likely than not, a meter  113  that is placed in the housing upside down is the result of an attempt to steal electric power. Accordingly a feature of the present meter  113  is that attempts to steal electrical power by mounting the meter upside down are detected by the detection of a reverse rotating disk and are frustrated because rotations of the disk  601  are accumulated regardless of direction. Controller  201  includes an alerting function that will flag reversed rotation and provide an indication of the reversal to server  101 .  
         [0069]    Controller  201  is programmed to recognize the above patterns and therefore knows what state should occur next, given a direction of rotation. If the pattern does not occur, a hardware failure has occurred and failure detection is indicated. The fault indication is also provided to server  101 .  
         [0070]    It should be noted that in some instances, a reversal of direction of rotation is not an indication of attempted theft, but a return of electrical power to the power grid. Controller  201  can be programmed to accumulate both forward and reverse direction power. In the normal instance, a customer would have to have pre-registered with the utility company to provide power back to the utility grid.  
         [0071]    The invention has been described in terms of embodiments of the invention. It will be apparent to those skilled in the art that various changes and modifications may be made to the embodiments shown and described without departing from either the spirit or scope of the invention. It is intended that the invention include all such changes and modifications. It is further intended that the invention not be limited to the illustrative embodiments shown and/or described. It is intended that the invention be limited only by the scope of the claims appended hereto.