US20230184866A1 - Generating simulated waveforms for an electric meter when operating in a simulation mode - Google Patents
Generating simulated waveforms for an electric meter when operating in a simulation mode Download PDFInfo
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01R—MEASURING ELECTRIC VARIABLES; MEASURING MAGNETIC VARIABLES
- G01R35/00—Testing or calibrating of apparatus covered by the other groups of this subclass
- G01R35/04—Testing or calibrating of apparatus covered by the other groups of this subclass of instruments for measuring time integral of power or current
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01R—MEASURING ELECTRIC VARIABLES; MEASURING MAGNETIC VARIABLES
- G01R22/00—Arrangements for measuring time integral of electric power or current, e.g. electricity meters
- G01R22/06—Arrangements for measuring time integral of electric power or current, e.g. electricity meters by electronic methods
- G01R22/061—Details of electronic electricity meters
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01R—MEASURING ELECTRIC VARIABLES; MEASURING MAGNETIC VARIABLES
- G01R22/00—Arrangements for measuring time integral of electric power or current, e.g. electricity meters
- G01R22/06—Arrangements for measuring time integral of electric power or current, e.g. electricity meters by electronic methods
- G01R22/10—Arrangements for measuring time integral of electric power or current, e.g. electricity meters by electronic methods using digital techniques
Definitions
- Implementations described herein relate to electric meters and, more particularly, to generating simulated waveforms for an electric meter.
- Electric meters measure and monitor electric energy.
- a meter In normal operating mode, a meter is connected to an electric distribution network and to a premises. The meter receives power signals from the electric distribution network that are complex, i.e., they include harmonics, offsets, phase shifts, and other variations, and processes the signals.
- a meter In order to develop, test, or validate meter functions, a meter is typically put into a simulation environment in which the meter may be connected to an external load box. The load box simulates the complex power signals that may be received by a meter when it is connected to the electric distribution network.
- load boxes are typically bulky and expensive. In addition, many load boxes are limited to providing signals for a single meter form.
- Some implementations described herein include a method for generating simulated waveforms by an electric meter.
- the method includes operating in a simulation mode. No external load device is required to be connected to an analog to digital converter (ADC) within the meter while operating in the simulation mode.
- the method includes generating simulated waveforms for a number of channels using waveform component values provided by a simulation interface component.
- the waveform component values for a channel include at least a voltage or a current value, a frequency value, and a phase value.
- the operations include generating a simulated channel waveform using the set of waveform component values for a channel at a rate that corresponds to a sampling rate of the ADC.
- the sampling rate of the ADC in simulation mode matches the sampling rate of the ADC in normal operating mode.
- the method further includes providing the simulated channel waveforms for the channels to a meter firmware interface.
- the meter firmware interface receives waveform data obtained from the ADC during normal operating mode.
- the meter firmware includes a waveform simulator, an event generator, and the meter firmware interface.
- the waveform simulator is configured to generate waveforms using the waveform components.
- the external simulation interface component may be connected to the meter and may provide waveform component values to the meter firmware, specifically to the waveform simulator and to the event generator. Waveform component values may be provided for different meter forms in order to generate simulated waveforms for multiple meter forms.
- FIG. 1 is an exploded perspective diagram of an exemplary electric meter configured to generate simulated waveforms, according to some implementations described herein.
- FIG. 2 is a block diagram illustrating a portion of a circuit board of an electric meter according to some implementations described herein.
- FIG. 3 is a block diagram of a computing device inputting data to a waveform simulator for generating simulated waveforms, according to some implementations described herein.
- FIG. 4 is a flowchart of a process of generating simulated waveforms, according to some implementations described herein.
- FIG. 5 is a flowchart of a process of generating events for simulated waveforms, according to some implementations described herein.
- an external load box is required when testing and validating electric meter functions and when developing new functions and capabilities.
- the external load box may include specialized hardware for providing electrical signals to the electric meter. Since the external load box may be relatively large and expensive, requiring a load box may limit testing and validation since it may be difficult to obtain or access a load box. Furthermore, the external load box may have limited testing capabilities. For example, the external load box may only provide signals for a single phase, so that multiple load boxes or multiple configurations of a single load box may be required to test different meter forms.
- the disclosed invention provides a waveform simulator and an event generator in the meter firmware.
- the waveform simulator generates simulated waveforms for a number of channels. For a single phase meter, the waveform simulator generates simulated waveforms for two channels, phase A voltage and phase A current. For a three-phase meter, the waveform simulator generates simulated waveforms for six channels, phase A voltage, phase A current, phase B voltage, phase B current, phase C voltage and phase C current.
- the meter can generate the simulated waveforms when the meter is operating in a simulation mode. While in the simulation mode, the waveform simulator can download waveform component values from an external component or tool and use the waveform component values to generate the simulated waveforms.
- the waveform simulator may generate the simulated waveforms at a rate that corresponds to a sampling rate of the analog to digital converter (ADC).
- ADC analog to digital converter
- the sampling rate of the ADC in simulation mode may be the same as a sample rate of the ADC in a normal operating mode.
- the meter firmware can include an event generator that can download event component values from the external component.
- the event generator can use the event component values to generate exemplary events, such as sag events or swell events, to be incorporated into the simulated waveforms.
- the waveform simulator may provide the simulated waveforms, which may include any simulated events, to a meter firmware interface.
- the meter firmware interface receives waveforms obtained from the ADC. Since the simulated waveforms are provided to the meter firmware interface and the meter firmware interface is located at a front end of the meter firmware, the meter firmware may be comprehensively tested using the simulated waveforms.
- FIG. 1 is an exploded perspective diagram of an exemplary electric meter 100 that may be configured to generate simulated waveforms, according to some implementations described herein.
- the electric meter 100 also referred to as a meter 100 , measures consumption of electricity and power characteristics.
- the meter 100 includes a meter housing 102 , an interior cover 104 , a circuit board 106 , and a meter base 108 .
- the meter housing 102 is a cylindrical open bottom structure that can be positioned on top of the interior cover 104 .
- the meter housing 102 can be at least partially transparent for viewing a display provided on the interior cover 104 beneath the meter housing 102 when the meter 100 is assembled.
- the interior cover 104 also has a cylindrical open bottom structure.
- the interior cover 104 can fit within the meter housing 102 and can be attached to the meter base 108 .
- the interior cover 104 may include a display 110 or other user interface that provides information, such as consumption data determined by the meter, that may be visible through the transparent meter housing 102 .
- the circuit board 106 is included within an interior of the interior cover 104 .
- the circuit board 106 may include components used to measure energy consumption, to communicate with the user interface, and to communicate on a network.
- the meter base 108 includes a main plate 112 , prongs 114 , and measurement circuitry (not shown). The circuit board 106 can be secured to the main plate 112 .
- the prongs 114 may extend from the back of the meter base 108 and may be used to mount the meter 100 into a meter socket.
- the measurement circuitry may measure current and/or voltage from power lines connected to the meter 100 when the meter is mounted to the socket and the socket is connected to a power distribution network.
- the meter 100 When the meter 100 is fully assembled (e.g., meter housing 102 and interior cover 104 attached to the meter base 108 ) and mounted into a socket at a premises, the meter 100 may operate in a normal operating mode and measure energy consumption.
- An ADC on the circuit board 106 may sample signals provided by the measurement circuitry.
- the ADC provides multiple channels of data, e.g., a voltage channel and a current channel per phase. Components on the circuit board 106 may perform further processing to determine power and/or consumption measurements.
- the waveform simulator may be used with other types of meters.
- FIG. 2 is a block diagram illustrating a portion of the circuit board 106 of an electric meter 100 connected to an external simulation interface component 204 , according to some implementations described herein.
- the circuit board 106 may include meter firmware 202 stored in a component on the circuit board, an ADC 206 , a direct memory access (DMA) component 208 , and random-access memory (RAM) 210 .
- DMA direct memory access
- RAM random-access memory
- the meter firmware 202 includes a waveform simulator 212 , an event generator 214 , a switch 216 , a compensation and adjustment block 218 , a meter form transformation block 220 , as well as other functions (not shown).
- the meter firmware interface 222 receives waveform data from either the output of the ADC or the output of the waveform simulator depending on the state of switch 216 , which may be implemented in the firmware as a software switch.
- the compensation and adjustment block 218 provides scaling, conversion, and calibration.
- the meter form transformation block 220 converts the native voltage and current ADC inputs to a mathematical form appropriate for the specific meter form (e.g., 2S, 9S, 12S, etc.) being measured.
- the output 224 of the meter form transformation block 220 may be used by the meter firmware to perform other functions, including detecting the fundamental frequency of the waveforms and determining consumption and power measurement calculations.
- the ADC 206 may sample signals from the measurement circuitry at an ADC sampling rate to generate multiple channels of data. For example, in a 3-phase meter, the ADC 206 may sample the signals using a sampling frequency of 14.648 kHz and may provide six channels of data, namely phase A voltage, phase A current, phase B voltage, phase B current, phase C voltage, and phase C current signals.
- the DMA 208 may provide the sampled data to the meter firmware 202 via the RAM 210 .
- the switch 216 is configured to provide the data from the ADC to the meter firmware interface 222 .
- switch 216 When the meter 100 is operating in a simulation mode, switch 216 is configured to provide the simulated waveforms from the waveform simulator 212 to the meter firmware interface 222 .
- One benefit of providing the simulated waveforms to the meter firmware interface is that it allows more accurate simulations. If simulated data is presented at a point downstream of the meter firmware interface, then portions of the firmware are bypassed during simulation.
- the meter may need to be in a certain mode, e.g., factory mode, or in a certain condition, e.g., disassembled and connected to a simulation interface component.
- the meter 100 is partially disassembled and a simulation interface component 204 is connected to the circuit board 106 .
- the simulation interface component 204 may be provided by an external computing device, such as the external computing device 302 depicted in FIG. 3 , that is communicatively coupled to the circuit board.
- the computing device 302 may be a laptop, desktop, or any other computing device that is suitable for inputting parameters to the waveform simulator 212 .
- a sensor When the meter is disassembled a sensor may detect the removal of the meter housing 102 and/or the interior cover 104 and may cause the meter to enter a factory mode. There may be other or alternative requirements to enter simulation mode. In some implementations, a user may be required to enter an additional key, which may be obtained from the manufacturer of the meter, or set a value to a predetermined value.
- the simulation interface component 204 may provide the waveform simulator with simulation component values, as well as enabling the meter 100 to operate in simulation mode.
- a user may enter the simulation component values via the simulation interface or may select a set of previously stored simulation component values.
- the simulation component values may include waveform component values, such as those shown in Table 1 depicted below. Different sets or tables of waveform component values may correspond to different meter forms. Table 1 shows example default values for a 9S meter form. Other tables may provide values for a 2S meter form or a 12S meter form, or a different set of default values for a 9S meter form.
- the waveform component values in Table 1 can include voltage or current values for each channel (such as RMS Voltage A or RMS Current A), frequency values (such as Line Frequency), phase values for each channel (such as phase A voltage angle or phase A current angle), and harmonic values for each channel and harmonic (such as Harmonic Magnitude and Harmonic Phase).
- the waveform component values enable the simulation of waveforms with multiple harmonics, where each harmonic is identified by a harmonic number and each harmonic is associated with a harmonic magnitude and harmonic phase.
- multiple harmonics for a single channel may be specified by providing harmonic magnitude and harmonic phase values for each harmonic number and associating the values with a channel number.
- the waveform simulator 212 may generate the simulated waveforms based on the waveform component values.
- the number of channels is based on the meter form being simulated. For a three-phase meter, there may be six channels, phase A voltage, phase A current, phase B voltage, phase B current, phase C voltage, and phase C current, and each channel may include harmonics.
- the simulation component values may also include event component values for simulating events.
- Exemplary events may include sag, swell, flicker, transients, service interruption, and power quality events.
- a user may configure the magnitude and duration of each event.
- the events may be queued such that multiple events can be defined and executed for any channel.
- the event component values may be inputted in the form of a table, such as in Table 2 depicted below.
- the event table can include multiple events.
- Table 2 depicts component values for two events.
- the magnitude of an event may be specified as a percentage, such as a percent change for voltage A or a percent change for current A.
- the duration of an event may be specified as a number of half line cycles.
- Each event may be defined by a set of values specifying a magnitude and a duration of the event.
- the Event Pointer component value specifies which event number to start on. For example, a value of 0 may specify starting on event 1 and a value of 1 may specify starting on event 2.
- the event generator 214 may generate one or more events in parallel with the waveform simulator 212 generating the simulated waveform data. The event generator 214 may transmit the events to the waveform simulator 212 .
- the method for generating simulated waveform data includes generating simulated sine waves for each harmonic specified for a channel and then summing the sine waves for the harmonics for that channel to generate a simulated channel waveform.
- the sine waves may be generated using the waveform component values such as the harmonic number magnitudes and the harmonic number phases.
- FIG. 4 is a flowchart of a process of generating simulated waveforms, according to some implementations described herein.
- FIG. 4 is discussed with respect to the components of the meter 100 depicted in FIGS. 1 - 2 , but is not limited to the illustrated components.
- the meter firmware 202 may receive an interrupt from the ADC 206 via the DMA 208 .
- the rate of the interrupt corresponds to the sample rate of the ADC.
- the rate of the interrupt in simulation mode is the same as the rate in operating mode.
- the interrupt triggers the generation of a new waveform sample for each channel.
- the waveform simulator 212 uses the waveform component values downloaded from the simulation interface component 204 to generate waveforms for each channel.
- the waveform component values for each channel may include a voltage or a current value, a frequency value, a phase value, and optionally a harmonic magnitude value, and a harmonic phase.
- the waveform simulator determines a maximum number of channels and a maximum number of harmonics for each channel based on the waveform component values.
- a value for the maximum number of channels and values for the maximum number of harmonics for each channel may be part of the downloaded values.
- the meter firmware 202 may determine the maximum number of channels or the maximum number of harmonics based on the valid waveform component values.
- any waveform components with a value of zero are not included in the simulation. If the values for RMS Voltage B and RMS Voltage C are zero, then the simulation is for a single-phase meter and the maximum number of channels is two, Phase A voltage and Phase A current.
- the waveform simulator 212 determines if a simulated channel waveform has been generated for all channels by comparing a channel count or the current channel number to the maximum number of channels. If the current channel number is less than the maximum number of channels, the process continues to block 406 . At block 406 , the waveform simulator 212 determines if all sine waves for the current channel have been generated for all harmonics for the current channel by comparing a current count of the harmonics generated for the current channel with a maximum number of harmonics for the current channel. If the current harmonic count is less than the maximum number of harmonics, the process continues to block 408 .
- the waveform simulator 212 generates harmonics for the current channel by multiplying the current harmonic number by an accumulated phase.
- the phase for the initial sample is specified by the waveform component values and the phase for subsequent samples is increased by 2 ⁇ (F L /F S ).
- the fundamental cumulative phase is represented by:
- the kth harmonic cumulative phase is represented by:
- the waveform simulator 212 adds the harmonic phase value (P harm ) for the current harmonic number.
- the waveform simulator 212 generates a sine wave using a least squares fit of a 9 th -order polynomial of a sine function. Since a sine function is an odd function only the odd coefficients of the polynomial are non-zero. Thus, the calculation only requires 5 non-zero coefficients.
- the sine wave is generated over an interval of [ ⁇ pi, pi].
- the sine wave may be represented as sin(kP n +P harm ), where k is the current harmonic number.
- the waveform simulator 212 adjusts a magnitude of the sine wave by the harmonic magnitude of the current harmonic number to generate a sine wave with harmonics. At this point, the harmonic count is adjusted to indicate that processing for the current harmonic number is complete.
- the process continues to block 406 .
- the waveform simulator 212 generates a simulated channel waveform for the current channel by summing the generated sine waves for all of the harmonics for the current channel. At this point the channel count is adjusted to indicate that processing for the current channel is complete.
- the process then continues to block 404 . If all channel waveforms have not been generated, then the process is repeated to generate an additional channel waveform. Once all simulated channel waveforms have been generated, the process continues to block 418 .
- the waveform simulator 212 outputs the simulated channel waveforms to the meter firmware interface 222 .
- the waveform simulator 212 may modify the simulated channel waveforms using events, such as sag or swell events, generated by the event generator 214 before outputting the simulated channel waveform to the meter firmware interface 222 .
- the method for generating events for a channel includes generating events based on event component values downloaded from the waveform simulator 212 .
- FIG. 5 is a flowchart of a process of generating events for a channel, according to some implementations described herein.
- FIG. 5 is discussed with respect to the components of the meter 100 depicted in FIGS. 1 - 2 , but other components may be used.
- the event generator 214 may receive the interrupt from the ADC 206 via the DMA 208 .
- the interrupt is the same as the interrupt received by the waveform simulator 212 in FIG. 4 .
- the event generator 214 uses event component values downloaded from a simulation interface component 204 .
- the event component values may include event magnitudes, event durations, and a maximum number of events for the current channel. In some examples, instead of receiving the maximum number of events, the event generator 214 may determine the maximum number of events by counting the number of valid event magnitudes or event durations downloaded from the simulation interface component 204 .
- the event generator determines whether an event is in progress. If an event is in progress, then then the process proceeds to block 508 . If an event is not in progress, then the process proceeds to block 504 .
- the event generator 214 determines if all events for the channel have been generated by comparing a current event number to the maximum number of events. If the current event number is less than the maximum number of events, the process continues to block 506 .
- the event generator 214 generates an event by generating an adjustment of the magnitude of the simulated waveform for the current channel for a time corresponding to the event duration.
- the event generator 214 may output the event to the waveform simulator 212 .
- the waveform simulator 212 may use the event to adjust the magnitude of the simulated channel waveform at block 418 in FIG. 4 before outputting the simulated channel waveform to the meter firmware interface 222 .
- the process may continue to block 508 . The process remains at block 508 until the event is completed. Once the event is completed, the current event number is incremented and the process proceeds to block 504 . Once all events for the current channel have been completed, the process may return to block 502 to wait for the next interrupt.
- a computing device can include any suitable arrangement of components that provide a result conditioned on one or more inputs.
- Suitable computing devices include multipurpose microprocessor-based computer systems accessing stored software (i.e., computer-readable instructions stored on a memory of the computer system) that programs or configures the computing system from a general-purpose computing apparatus to a specialized computing apparatus implementing one or more aspects of the present subject matter. Any suitable programming, scripting, or other type of language or combinations of languages may be used to implement the teachings contained herein in software to be used in programming or configuring a computing device.
- aspects of the methods disclosed herein may be performed in the operation of such computing devices.
- the order of the blocks presented in the examples above can be varied; for example, blocks can be re-ordered, combined, and/or broken into sub-blocks. Certain blocks or processes can be performed in parallel.
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Abstract
Description
- Implementations described herein relate to electric meters and, more particularly, to generating simulated waveforms for an electric meter.
- Electric meters measure and monitor electric energy. In normal operating mode, a meter is connected to an electric distribution network and to a premises. The meter receives power signals from the electric distribution network that are complex, i.e., they include harmonics, offsets, phase shifts, and other variations, and processes the signals. In order to develop, test, or validate meter functions, a meter is typically put into a simulation environment in which the meter may be connected to an external load box. The load box simulates the complex power signals that may be received by a meter when it is connected to the electric distribution network. Such load boxes are typically bulky and expensive. In addition, many load boxes are limited to providing signals for a single meter form.
- Some implementations described herein include a method for generating simulated waveforms by an electric meter. The method includes operating in a simulation mode. No external load device is required to be connected to an analog to digital converter (ADC) within the meter while operating in the simulation mode. The method includes generating simulated waveforms for a number of channels using waveform component values provided by a simulation interface component. The waveform component values for a channel include at least a voltage or a current value, a frequency value, and a phase value. The operations include generating a simulated channel waveform using the set of waveform component values for a channel at a rate that corresponds to a sampling rate of the ADC. The sampling rate of the ADC in simulation mode matches the sampling rate of the ADC in normal operating mode. The method further includes providing the simulated channel waveforms for the channels to a meter firmware interface. The meter firmware interface receives waveform data obtained from the ADC during normal operating mode.
- In some implementations, the meter firmware includes a waveform simulator, an event generator, and the meter firmware interface. The waveform simulator is configured to generate waveforms using the waveform components. The external simulation interface component may be connected to the meter and may provide waveform component values to the meter firmware, specifically to the waveform simulator and to the event generator. Waveform component values may be provided for different meter forms in order to generate simulated waveforms for multiple meter forms.
- These illustrative aspects and features are mentioned not to limit or define the presently described subject matter, but to provide examples to aid understanding of the concepts described in this application. Other aspects, advantages, and features of the presently described subject matter will become apparent after review of the entire application.
- These and other features, aspects, and advantages of the present disclosure are better understood when the following Detailed Description is read with reference to the accompanying drawings.
-
FIG. 1 is an exploded perspective diagram of an exemplary electric meter configured to generate simulated waveforms, according to some implementations described herein. -
FIG. 2 is a block diagram illustrating a portion of a circuit board of an electric meter according to some implementations described herein. -
FIG. 3 is a block diagram of a computing device inputting data to a waveform simulator for generating simulated waveforms, according to some implementations described herein. -
FIG. 4 is a flowchart of a process of generating simulated waveforms, according to some implementations described herein. -
FIG. 5 is a flowchart of a process of generating events for simulated waveforms, according to some implementations described herein. - Conventionally, an external load box is required when testing and validating electric meter functions and when developing new functions and capabilities. The external load box may include specialized hardware for providing electrical signals to the electric meter. Since the external load box may be relatively large and expensive, requiring a load box may limit testing and validation since it may be difficult to obtain or access a load box. Furthermore, the external load box may have limited testing capabilities. For example, the external load box may only provide signals for a single phase, so that multiple load boxes or multiple configurations of a single load box may be required to test different meter forms.
- To address these issues, the disclosed invention provides a waveform simulator and an event generator in the meter firmware. The waveform simulator generates simulated waveforms for a number of channels. For a single phase meter, the waveform simulator generates simulated waveforms for two channels, phase A voltage and phase A current. For a three-phase meter, the waveform simulator generates simulated waveforms for six channels, phase A voltage, phase A current, phase B voltage, phase B current, phase C voltage and phase C current.
- The meter can generate the simulated waveforms when the meter is operating in a simulation mode. While in the simulation mode, the waveform simulator can download waveform component values from an external component or tool and use the waveform component values to generate the simulated waveforms. The waveform simulator may generate the simulated waveforms at a rate that corresponds to a sampling rate of the analog to digital converter (ADC). The sampling rate of the ADC in simulation mode may be the same as a sample rate of the ADC in a normal operating mode.
- Additionally, the meter firmware can include an event generator that can download event component values from the external component. The event generator can use the event component values to generate exemplary events, such as sag events or swell events, to be incorporated into the simulated waveforms.
- The waveform simulator may provide the simulated waveforms, which may include any simulated events, to a meter firmware interface. In a normal operating mode, the meter firmware interface receives waveforms obtained from the ADC. Since the simulated waveforms are provided to the meter firmware interface and the meter firmware interface is located at a front end of the meter firmware, the meter firmware may be comprehensively tested using the simulated waveforms.
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FIG. 1 is an exploded perspective diagram of an exemplaryelectric meter 100 that may be configured to generate simulated waveforms, according to some implementations described herein. In some implementations, theelectric meter 100, also referred to as ameter 100, measures consumption of electricity and power characteristics. Themeter 100 includes ameter housing 102, aninterior cover 104, acircuit board 106, and ameter base 108. Themeter housing 102 is a cylindrical open bottom structure that can be positioned on top of theinterior cover 104. In some examples, themeter housing 102 can be at least partially transparent for viewing a display provided on theinterior cover 104 beneath themeter housing 102 when themeter 100 is assembled. - The
interior cover 104 also has a cylindrical open bottom structure. Theinterior cover 104 can fit within themeter housing 102 and can be attached to themeter base 108. Theinterior cover 104 may include adisplay 110 or other user interface that provides information, such as consumption data determined by the meter, that may be visible through thetransparent meter housing 102. Thecircuit board 106 is included within an interior of theinterior cover 104. Thecircuit board 106 may include components used to measure energy consumption, to communicate with the user interface, and to communicate on a network. Themeter base 108 includes amain plate 112,prongs 114, and measurement circuitry (not shown). Thecircuit board 106 can be secured to themain plate 112. Theprongs 114 may extend from the back of themeter base 108 and may be used to mount themeter 100 into a meter socket. The measurement circuitry may measure current and/or voltage from power lines connected to themeter 100 when the meter is mounted to the socket and the socket is connected to a power distribution network. - When the
meter 100 is fully assembled (e.g.,meter housing 102 andinterior cover 104 attached to the meter base 108) and mounted into a socket at a premises, themeter 100 may operate in a normal operating mode and measure energy consumption. An ADC on thecircuit board 106 may sample signals provided by the measurement circuitry. Typically, the ADC provides multiple channels of data, e.g., a voltage channel and a current channel per phase. Components on thecircuit board 106 may perform further processing to determine power and/or consumption measurements. Although one type of meter is depicted inFIG. 1 , the waveform simulator may be used with other types of meters. - In addition to a standard operating mode, the meter may also operate in a simulation mode where instead of using inputs provided by the measurement circuitry and the ADC, the meter uses simulated waveforms and simulated events.
FIG. 2 is a block diagram illustrating a portion of thecircuit board 106 of anelectric meter 100 connected to an externalsimulation interface component 204, according to some implementations described herein. Thecircuit board 106 may includemeter firmware 202 stored in a component on the circuit board, anADC 206, a direct memory access (DMA)component 208, and random-access memory (RAM) 210. Themeter firmware 202 includes awaveform simulator 212, anevent generator 214, aswitch 216, a compensation and adjustment block 218, a meterform transformation block 220, as well as other functions (not shown). Themeter firmware interface 222 receives waveform data from either the output of the ADC or the output of the waveform simulator depending on the state ofswitch 216, which may be implemented in the firmware as a software switch. - The compensation and adjustment block 218 provides scaling, conversion, and calibration. The meter
form transformation block 220 converts the native voltage and current ADC inputs to a mathematical form appropriate for the specific meter form (e.g., 2S, 9S, 12S, etc.) being measured. Theoutput 224 of the meterform transformation block 220 may be used by the meter firmware to perform other functions, including detecting the fundamental frequency of the waveforms and determining consumption and power measurement calculations. - When the
meter 100 is operating in a normal operating mode, theADC 206 may sample signals from the measurement circuitry at an ADC sampling rate to generate multiple channels of data. For example, in a 3-phase meter, theADC 206 may sample the signals using a sampling frequency of 14.648 kHz and may provide six channels of data, namely phase A voltage, phase A current, phase B voltage, phase B current, phase C voltage, and phase C current signals. TheDMA 208 may provide the sampled data to themeter firmware 202 via theRAM 210. In normal operating mode, theswitch 216 is configured to provide the data from the ADC to themeter firmware interface 222. - When the
meter 100 is operating in a simulation mode,switch 216 is configured to provide the simulated waveforms from thewaveform simulator 212 to themeter firmware interface 222. One benefit of providing the simulated waveforms to the meter firmware interface is that it allows more accurate simulations. If simulated data is presented at a point downstream of the meter firmware interface, then portions of the firmware are bypassed during simulation. - To enter simulation mode, the meter may need to be in a certain mode, e.g., factory mode, or in a certain condition, e.g., disassembled and connected to a simulation interface component. In one example, the
meter 100 is partially disassembled and asimulation interface component 204 is connected to thecircuit board 106. Thesimulation interface component 204 may be provided by an external computing device, such as theexternal computing device 302 depicted inFIG. 3 , that is communicatively coupled to the circuit board. Thecomputing device 302 may be a laptop, desktop, or any other computing device that is suitable for inputting parameters to thewaveform simulator 212. - When the meter is disassembled a sensor may detect the removal of the
meter housing 102 and/or theinterior cover 104 and may cause the meter to enter a factory mode. There may be other or alternative requirements to enter simulation mode. In some implementations, a user may be required to enter an additional key, which may be obtained from the manufacturer of the meter, or set a value to a predetermined value. - The
simulation interface component 204 may provide the waveform simulator with simulation component values, as well as enabling themeter 100 to operate in simulation mode. A user may enter the simulation component values via the simulation interface or may select a set of previously stored simulation component values. The simulation component values may include waveform component values, such as those shown in Table 1 depicted below. Different sets or tables of waveform component values may correspond to different meter forms. Table 1 shows example default values for a 9S meter form. Other tables may provide values for a 2S meter form or a 12S meter form, or a different set of default values for a 9S meter form. -
TABLE 1 WAVEFORM COMPONENT VALUES METER LOAD SIMULATION 0-Meter Load Simulation ENABLE is disabled LINE FREQUENCY 60 Hz RMS VOLTAGE A 120 Volts RMS VOLTAGE B 120 Volts RMS VOLTAGE C 120 Volts RMS CURRENT A 2.5 Amps RMS CURRENT B 2.5 Amps RMS CURRENT C 2.5 Amps PHASE A VOLTAGE ANGLE 0 Degrees PHASE B VOLTAGE ANGLE 120 Degrees PHASE C VOLTAGE ANGLE −120 Degrees PHASE A CURRENT ANGLE 0 Degrees PHASE B CURRENT ANGLE 120 Degrees PHASE C CURRENT ANGLE −120 Degrees DC OFFSET VOLTAGE A 0.1 Volts DC OFFSET VOLTAGE B 0.2 Volts DC OFFSET VOLTAGE C 0.3 Volts DC OFFSET CURRENT A 0.01 Amps DC OFFSET CURRENT B 0.02 Amps DC OFFSET CURRENT C 0.03 Amps Number of Harmonics Voltage A 2 Number of Harmonics Voltage B 2 Number of Harmonics Voltage C 2 Number of Harmonics Current A 2 Number of Harmonics Current B 2 Number of Harmonics Current C 2 Harmonic Number 1 for Voltage A 1 Harmonic Number 2 for Voltage A 3 Harmonic Number 1 for Voltage B 1 Harmonic Number 2 for Voltage B 5 Harmonic Number 1 for Voltage C 1 Harmonic Number 2 for Voltage C 7 Harmonic Number 1 for Current A 1 Harmonic Number 2 for Current A 9 Harmonic Number 1 for Current B 1 Harmonic Number 2 for Current B 11 Harmonic Number 1 for Current C 1 Harmonic Number 2 for Current C 13 HARMONIC MAGNITUDE 1 VOLTAGE A 100% HARMONIC MAGNITUDE 2 VOLTAGE A 33% HARMONIC MAGNITUDE 1 VOLTAGE B 100% HARMONIC MAGNITUDE 2 VOLTAGE B 20% HARMONIC MAGNITUDE 1 VOLTAGE C 100% HARMONIC MAGNITUDE 2 VOLTAGE C 14% HARMONIC MAGNITUDE 1 CURRENT A 100% HARMONIC MAGNITUDE 2 CURRENT A 11% HARMONIC MAGNITUDE 1 CURRENT B 100% HARMONIC MAGNITUDE 2 CURRENT B 9% HARMONIC MAGNITUDE 1 CURRENT C 100% HARMONIC MAGNITUDE 2 CURRENT C 7% HARMONIC PHASE 1 VOLTAGE A 0 Degrees HARMONIC PHASE 2 VOLTAGE A 2 Degrees HARMONIC PHASE 1 VOLTAGE B 0 Degrees HARMONIC PHASE 2 VOLTAGE B 4 Degrees HARMONIC PHASE 1 VOLTAGE C 0 Degrees HARMONIC PHASE 2 VOLTAGE C −2 Degrees HARMONIC PHASE 1 CURRENT A 0 Degrees HARMONIC PHASE 2 CURRENT A 3 Degrees HARMONIC PHASE 1 CURRENT B 0 Degrees HARMONIC PHASE 2 CURRENT B 6 Degrees HARMONIC PHASE 1 CURRENT C 0 Degrees HARMONIC PHASE 2 CURRENT C −3 Degrees - The waveform component values in Table 1 can include voltage or current values for each channel (such as RMS Voltage A or RMS Current A), frequency values (such as Line Frequency), phase values for each channel (such as phase A voltage angle or phase A current angle), and harmonic values for each channel and harmonic (such as Harmonic Magnitude and Harmonic Phase). The waveform component values enable the simulation of waveforms with multiple harmonics, where each harmonic is identified by a harmonic number and each harmonic is associated with a harmonic magnitude and harmonic phase. In Table 1, multiple harmonics for a single channel may be specified by providing harmonic magnitude and harmonic phase values for each harmonic number and associating the values with a channel number. The
waveform simulator 212 may generate the simulated waveforms based on the waveform component values. The number of channels is based on the meter form being simulated. For a three-phase meter, there may be six channels, phase A voltage, phase A current, phase B voltage, phase B current, phase C voltage, and phase C current, and each channel may include harmonics. - In addition to the waveform component values, the simulation component values may also include event component values for simulating events. Exemplary events may include sag, swell, flicker, transients, service interruption, and power quality events. A user may configure the magnitude and duration of each event. The events may be queued such that multiple events can be defined and executed for any channel. The event component values may be inputted in the form of a table, such as in Table 2 depicted below.
-
TABLE 2 EVENT COMPONENT VALUES EVENT GENERATION FLAG 0-Disable Event Generation EVENT GENERATION START 0-Stop Event Generation EVENT POINTER 0 NUMBER OF EVENTS 2 HALF CYCLE COUNTER 0 EVENT DURATION IN HALF LINE 120 CYCLES 1 PERCENT CHANGE 1 VOLTAGE A 100 PERCENT CHANGE 1 VOLTAGE B 30 PERCENT CHANGE 1 VOLTAGE C 100 PERCENT CHANGE 1 CURRENT A 100 PERCENT CHANGE 1 CURRENT B 100 PERCENT CHANGE 1 CURRENT C 100 EVENT DURATION IN HALF LINE 240 CYCLES 2 PERCENT CHANGE 2 VOLTAGE A 100 PERCENT CHANGE 2 VOLTAGE B 100 PERCENT CHANGE 2 VOLTAGE C 100 PERCENT CHANGE 2 CURRENT A 20 PERCENT CHANGE 2 CURRENT B 100 PERCENT CHANGE 2 CURRENT C 100 - The event table can include multiple events. For example, Table 2 depicts component values for two events. The magnitude of an event may be specified as a percentage, such as a percent change for voltage A or a percent change for current A. The duration of an event may be specified as a number of half line cycles. Each event may be defined by a set of values specifying a magnitude and a duration of the event. The Event Pointer component value specifies which event number to start on. For example, a value of 0 may specify starting on event 1 and a value of 1 may specify starting on event 2. The
event generator 214 may generate one or more events in parallel with thewaveform simulator 212 generating the simulated waveform data. Theevent generator 214 may transmit the events to thewaveform simulator 212. - The method for generating simulated waveform data includes generating simulated sine waves for each harmonic specified for a channel and then summing the sine waves for the harmonics for that channel to generate a simulated channel waveform. The sine waves may be generated using the waveform component values such as the harmonic number magnitudes and the harmonic number phases. Once all the harmonics for all the channels are processed, the simulated channel waveforms are provided to the meter firmware interface.
-
FIG. 4 is a flowchart of a process of generating simulated waveforms, according to some implementations described herein.FIG. 4 is discussed with respect to the components of themeter 100 depicted inFIGS. 1-2 , but is not limited to the illustrated components. Atblock 402, themeter firmware 202 may receive an interrupt from theADC 206 via theDMA 208. The rate of the interrupt corresponds to the sample rate of the ADC. The rate of the interrupt in simulation mode is the same as the rate in operating mode. The interrupt triggers the generation of a new waveform sample for each channel. Thewaveform simulator 212 uses the waveform component values downloaded from thesimulation interface component 204 to generate waveforms for each channel. The waveform component values for each channel may include a voltage or a current value, a frequency value, a phase value, and optionally a harmonic magnitude value, and a harmonic phase. The waveform simulator determines a maximum number of channels and a maximum number of harmonics for each channel based on the waveform component values. In some examples, a value for the maximum number of channels and values for the maximum number of harmonics for each channel may be part of the downloaded values. In other examples, rather than downloading the maximum number of channels or the maximum number of harmonics, themeter firmware 202 may determine the maximum number of channels or the maximum number of harmonics based on the valid waveform component values. For example, if a waveform component value of zero is an invalid value, then any waveform components with a value of zero are not included in the simulation. If the values for RMS Voltage B and RMS Voltage C are zero, then the simulation is for a single-phase meter and the maximum number of channels is two, Phase A voltage and Phase A current. - At
block 404, thewaveform simulator 212 determines if a simulated channel waveform has been generated for all channels by comparing a channel count or the current channel number to the maximum number of channels. If the current channel number is less than the maximum number of channels, the process continues to block 406. Atblock 406, thewaveform simulator 212 determines if all sine waves for the current channel have been generated for all harmonics for the current channel by comparing a current count of the harmonics generated for the current channel with a maximum number of harmonics for the current channel. If the current harmonic count is less than the maximum number of harmonics, the process continues to block 408. - At
block 408, thewaveform simulator 212 generates harmonics for the current channel by multiplying the current harmonic number by an accumulated phase. The phase for the initial sample is specified by the waveform component values and the phase for subsequent samples is increased by 2 π (FL/FS). The fundamental cumulative phase is represented by: -
P n+1 =P n+2π(F L /F S) - where Pn is the phase of the previously generated sample, FL is the line frequency, and FS is the sampling frequency of the ADC.
- The kth harmonic cumulative phase is represented by:
-
kP n+1 =k(P n+2π(F L /F S)) - where k=1, 2, . . . (up to the number of harmonics to generate).
- At
block 410, thewaveform simulator 212 adds the harmonic phase value (Pharm) for the current harmonic number. Atblock 412, thewaveform simulator 212 generates a sine wave using a least squares fit of a 9th-order polynomial of a sine function. Since a sine function is an odd function only the odd coefficients of the polynomial are non-zero. Thus, the calculation only requires 5 non-zero coefficients. The sine wave is generated over an interval of [−pi, pi]. The sine wave may be represented as sin(kPn+Pharm), where k is the current harmonic number. - At
block 414, thewaveform simulator 212 adjusts a magnitude of the sine wave by the harmonic magnitude of the current harmonic number to generate a sine wave with harmonics. At this point, the harmonic count is adjusted to indicate that processing for the current harmonic number is complete. The process continues to block 406. Once sine waves have been generated for all harmonic numbers for the current channel, the process continues to block 416. Atblock 416, thewaveform simulator 212 generates a simulated channel waveform for the current channel by summing the generated sine waves for all of the harmonics for the current channel. At this point the channel count is adjusted to indicate that processing for the current channel is complete. The process then continues to block 404. If all channel waveforms have not been generated, then the process is repeated to generate an additional channel waveform. Once all simulated channel waveforms have been generated, the process continues to block 418. Atblock 418, thewaveform simulator 212 outputs the simulated channel waveforms to themeter firmware interface 222. - In some examples, the
waveform simulator 212 may modify the simulated channel waveforms using events, such as sag or swell events, generated by theevent generator 214 before outputting the simulated channel waveform to themeter firmware interface 222. The method for generating events for a channel includes generating events based on event component values downloaded from thewaveform simulator 212. -
FIG. 5 is a flowchart of a process of generating events for a channel, according to some implementations described herein.FIG. 5 is discussed with respect to the components of themeter 100 depicted inFIGS. 1-2 , but other components may be used. Atblock 502, theevent generator 214 may receive the interrupt from theADC 206 via theDMA 208. The interrupt is the same as the interrupt received by thewaveform simulator 212 inFIG. 4 . Theevent generator 214 uses event component values downloaded from asimulation interface component 204. The event component values may include event magnitudes, event durations, and a maximum number of events for the current channel. In some examples, instead of receiving the maximum number of events, theevent generator 214 may determine the maximum number of events by counting the number of valid event magnitudes or event durations downloaded from thesimulation interface component 204. - At
block 503, the event generator determines whether an event is in progress. If an event is in progress, then then the process proceeds to block 508. If an event is not in progress, then the process proceeds to block 504. Atblock 504, theevent generator 214 determines if all events for the channel have been generated by comparing a current event number to the maximum number of events. If the current event number is less than the maximum number of events, the process continues to block 506. - At
block 506, theevent generator 214 generates an event by generating an adjustment of the magnitude of the simulated waveform for the current channel for a time corresponding to the event duration. Theevent generator 214 may output the event to thewaveform simulator 212. In some examples, thewaveform simulator 212 may use the event to adjust the magnitude of the simulated channel waveform atblock 418 inFIG. 4 before outputting the simulated channel waveform to themeter firmware interface 222. The process may continue to block 508. The process remains atblock 508 until the event is completed. Once the event is completed, the current event number is incremented and the process proceeds to block 504. Once all events for the current channel have been completed, the process may return to block 502 to wait for the next interrupt. - Numerous specific details are set forth herein to provide a thorough understanding of the claimed subject matter. However, those skilled in the art will understand that the claimed subject matter may be practiced without these specific details. In other instances, methods, apparatuses, or systems that would be known by one of ordinary skill have not been described in detail so as not to obscure claimed subject matter.
- The features discussed herein are not limited to any particular hardware architecture or configuration. A computing device can include any suitable arrangement of components that provide a result conditioned on one or more inputs. Suitable computing devices include multipurpose microprocessor-based computer systems accessing stored software (i.e., computer-readable instructions stored on a memory of the computer system) that programs or configures the computing system from a general-purpose computing apparatus to a specialized computing apparatus implementing one or more aspects of the present subject matter. Any suitable programming, scripting, or other type of language or combinations of languages may be used to implement the teachings contained herein in software to be used in programming or configuring a computing device.
- Aspects of the methods disclosed herein may be performed in the operation of such computing devices. The order of the blocks presented in the examples above can be varied; for example, blocks can be re-ordered, combined, and/or broken into sub-blocks. Certain blocks or processes can be performed in parallel.
- The use of “configured to” herein is meant as open and inclusive language that does not foreclose devices configured to perform additional tasks or steps. Additionally, the use of “based on” is meant to be open and inclusive, in that a process, step, calculation, or other action “based on” one or more recited conditions or values may, in practice, be based on additional conditions or values beyond those recited. Headings, lists, and numbering included herein are for ease of explanation only and are not meant to be limiting.
- While the present subject matter has been described in detail with respect to specific aspects thereof, it will be appreciated that those skilled in the art, upon attaining an understanding of the foregoing, may readily produce alterations to, variations of, and equivalents to such aspects. Accordingly, it should be understood that the present disclosure has been presented for purposes of example rather than limitation and does not preclude inclusion of such modifications, variations, and/or additions to the present subject matter as would be readily apparent to one of ordinary skill in the art.
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CN202280082258.3A CN118401853A (en) | 2021-12-13 | 2022-12-06 | Generating analog waveforms for an electricity meter |
AU2022416067A AU2022416067A1 (en) | 2021-12-13 | 2022-12-06 | Generating simulated waveforms for an electric meter |
CA3240476A CA3240476A1 (en) | 2021-12-13 | 2022-12-06 | Generating simulated waveforms for an electric meter |
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US7513683B2 (en) * | 2006-10-10 | 2009-04-07 | M & Fc Holding, Llc | Method, apparatus, and system for detecting hot socket deterioration in an electrical meter connection |
US9506950B2 (en) * | 2014-03-17 | 2016-11-29 | Landis+Gyr, Inc. | Tampering detection for an electric meter |
US10393791B2 (en) * | 2017-09-28 | 2019-08-27 | Landis+Gyr Llc | Detection of deteriorated electrical connections in a meter using temperature sensing and time-variable thresholds |
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US6711509B2 (en) * | 2001-04-02 | 2004-03-23 | Square D Company | Impulsive transient hardware simulation |
US6815942B2 (en) * | 2001-09-25 | 2004-11-09 | Landis+Gyr, Inc. | Self-calibrating electricity meter |
US10033400B1 (en) * | 2017-10-18 | 2018-07-24 | Schweitzer Engineering Laboratories, Inc. | Analog-to-digital converter verification using quantization noise properties |
BE1026732B1 (en) * | 2018-10-26 | 2020-06-03 | Phoenix Contact Gmbh & Co | Measuring device |
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US7513683B2 (en) * | 2006-10-10 | 2009-04-07 | M & Fc Holding, Llc | Method, apparatus, and system for detecting hot socket deterioration in an electrical meter connection |
US9506950B2 (en) * | 2014-03-17 | 2016-11-29 | Landis+Gyr, Inc. | Tampering detection for an electric meter |
US10393791B2 (en) * | 2017-09-28 | 2019-08-27 | Landis+Gyr Llc | Detection of deteriorated electrical connections in a meter using temperature sensing and time-variable thresholds |
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