• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:
    digital signal processing for plc communications with communication frequencies. aspects of the present invention relate to receiving devices and methods of using them. one such method includes converting, using an analog-to-digital converter (cad), an analog input signal from power distribution lines that carry power using alternating current (ac) into a digital format. this digital input signal can be an oversampled digital signal, where the digital signal is oversampled relative to downstream processing (eg, fft-based processing). one or more processing circuits can then be used to decimate the digital input signal according to a decimation rate. a reference signal may be generated by the processing circuit in response to the decimation rate. the processing circuit can also be used to detect a change in phase difference between ac and the reference signal and modify the decimation rate in response to detecting a change in phase difference in order to counteract the detect change. in the phase difference.
    公开号:BR112014015159B1
    申请号:R112014015159-8
    申请日:2012-12-14
    公开日:2021-08-24
    发明作者:Stuart L. Haug;Chad Wolter;Bryce D. Johnson
    申请人:Landis+Gyr Technologies, Llc;
    IPC主号:
    专利说明:

    Related Patent Document
    [001]This patent document claims priority to US Patent Application Serial No. 13/334,522, filed December 22, 2011, the contents of which are incorporated herein by reference in its entirety. Background of the Invention
    [002]Service providers use distributed networks to offer services to customers across large geographic areas. For example, energy companies use power distribution lines to transport energy from one or more generating stations (power plants) to customers' residential and commercial sites. Generating stations use alternating current (AC) to transmit power over long distances through power distribution lines. Long-distance transmission can be performed using relatively high electrical voltage. Substations close to customer sites make it possible to lower the high voltage to a lower voltage (eg by using transformers). Power distribution lines carry this lower voltage AC from substations to terminal devices at customer sites.
    [003] Communication providers can use a distributed communication network to offer communication services to customers. Similarly, energy companies use a network of power lines, meters and other network elements to bring energy to customers across multiple geographic regions and receive data from customer locations, including, but not limited to, representative consumption data . A system can fulfill these dissemination functions using a set of data collection devices (collectors) designed to communicate with nearby terminal devices. However, data communication between a command center, collectors and many thousands of terminal devices along power distribution lines can be a particularly challenging problem. The sheer number of terminal devices contributes to a multitude of problems, which include terminal power processing, memory size, terminal cost, AC power interference, and other concerns. For example, processing digital signals for communication between devices can be complicated due to these and other factors. Invention Summary
    [004] Certain aspects of the present invention pertain to systems and methods for use with receiver circuits that track the AC frequency. These and other aspects of the present invention are exemplified in several illustrated implementations and applications, some of which are represented in the figures and characterized in the claims section below.
    [005] Specific embodiments of the present invention relate to a circuit-based apparatus with a transceiver circuit configured and arranged to communicate through power distribution lines that carry energy using alternating current (AC). One or more processing circuits are configured and arranged to provide an analog-to-digital converter (CAD) module configured to generate a digital input signal from an analog signal received in the transceiver circuit. This digital input signal can be an oversampled digital signal, where the digital signal is oversampled with respect to downstream processing (eg FFT-based processing). A decimator module is configured and arranged to produce, in response to a variable decimation rate, a decimated version of the digital input signal by decimating the oversampled signal in order to decrease the sampling rate. A reference signal generator module is configured and arranged to generate a reference signal with a frequency in response to the decimation rate. A decimation modification module is configured and arranged to modify the decimation rate, in response to an indication of a change in phase difference between the reference signal and the AC, in order to neutralize the phase difference. This can be particularly useful for maintaining a close correlation between transmitted signal frequencies (which vary with AC frequency) and signal processing (which can use an FFT with a frequency-varying sampling rate of CA).
    [006] Other embodiments relate to methods for using one or more circuits of a receiving device. One such method includes converting, using an analog-to-digital converter (CAD), an analog input signal from power distribution lines that carry power using alternating current (AC) into a digital format. This digital input signal can be an over-sampled digital signal, where the digital signal is over-sampled with respect to downstream processing (eg FFT-based processing). One or more processing circuits can then be used to decimate the digital input signal according to a decimation rate. A reference signal is generated by the processing circuit in response to the decimation rate. The processing circuit can also be used to detect a change in phase difference between the AC and the reference signal and modify the decimation rate, in response to detecting a change in phase difference, in order to counteract the detected change. in the phase difference.
    [007] The above summary is not intended to describe each illustrated embodiment or all implementations of the present invention. The following figures and detailed description, including that described in the appended claims, more specifically describe some of these embodiments. Brief Description of Drawings
    [008] Several exemplary embodiments can be understood further in light of the detailed description below together with the attached drawings, among which:
    [009]a FIG. 1 is a block diagram of a power line communication system in which terminals communicate data to collector units in accordance with some embodiments of the present invention;
    [010]a FIG. 2 illustrates a block diagram for a collector device in accordance with some embodiments of the present invention; and
    [011]a FIG. 3 illustrates another block diagram for a collector device that may be disposed in a distribution substation in accordance with some embodiments of the present invention.
    [012] Although the invention is susceptible to various modifications and alternative forms, examples of it are given by way of example in the drawings and will be described in detail. It should be kept in mind, however, that it is not intended to limit the invention to the specific embodiments illustrated and/or described. Rather, it is intended to cover all modifications, equivalents and alternatives included within the scope and essence of the invention. Detailed Description
    [013] It is believed that aspects of the present invention apply to many different types of devices, systems and structures, including those that can be implemented by receiver circuits that communicate through power distribution lines. While the present invention is not necessarily limited to such applications, it is possible to recognize various aspects of the invention by discussing various examples using that context.
    [014]Exemplary embodiments of the present invention refer to receiver circuits configured and arranged to process communication signals received through power distribution lines, which transport energy using alternating current (AC). Receiver circuits can be configured to process received signals using AC as a time reference. The AC line frequency is subject to significant fluctuations, and the receiver is designed to compensate for these fluctuations by making proper adjustments to signal processing.
    [015]According to certain embodiments of the present invention, the bandwidth demands of a complex system that communicates through power distribution lines are satisfied using a receiver that processes a signal received in the digital domain. In specific embodiments, signal processing includes the use of a fast Fourier transform (FFT) to allow for representation of the signal in the frequency domain. The FFT algorithm can be developed to match the channel frequencies used by the transmitter. Embodiments of the present invention therefore deal with compensating for changes in channel frequencies arising from corresponding changes in AC frequency.
    [016]For example, transmitted signals can follow the AC line frequency in certain embodiments. For example, a given frequency channel can be determined using the AC line frequency as a reference or clock signal. In this case, the frequency channel has a center frequency that would vary as the AC line frequency varied. This can be particularly useful for filtering out harmonics that can be caused by AC supplying power. This AC frequency, and the resulting harmonics, can range around an ideal frequency of about 60 Hz in the United States and about 50 Hz in Europe. These standard frequencies, however, are relatively arbitrary (eg defined by a standard that could change in the future) and do not necessarily limit the various embodiments discussed in this document.
    [017]The output of an FFT can vary according to a number of input parameters. One of these parameters is the sampling rate for the FFT-transformed digital signal. Embodiments of the present invention aim to adjust the sampling rate that is fed to the FFT. Sampling rate adjustment can be performed by modifying the decimation rate of the oversampled signal in order to counteract changes in AC frequency.
    [018] Certain aspects of the present invention pertain to a receiver circuit in a data collection device (collector) configured and arranged to lock its signal processing (for example, an FFT algorithm) close enough to the line frequency for the demodulation of complex data received from the terminals. The ability to lock efficiently and effectively can be particularly useful for allowing a large number of densely packed frequency channels in a limited bandwidth, where the frequencies of the different channels are held to extremely tight tolerances. For example, the present invention can be particularly useful for maintaining orthogonality between subchannels throughout the system bandwidth.
    [019] In a specific embodiment, the upstream receiver resampling rate is closely matched to the power line frequency (eg, within 1 part per 10 million) and to facilitate the demodulation of signals from the terminals with a receiver based on the FFT.
    [020] Specific embodiments of the present invention relate to a circuit-based apparatus with a transceiver circuit configured and arranged to communicate through power distribution lines that carry energy using alternating current (AC). One or more processing circuits are configured and arranged to provide an analog-to-digital converter (CAD) module configured to generate a digital input signal from an analog signal received in the transceiver circuit. This digital input signal can be an oversampled digital signal, where the digital signal is oversampled with respect to downstream processing (eg FFT-based processing). A decimator module is configured and arranged to produce, in response to a variable decimation rate, a decimated version of the digital input signal by decimating the oversampled signal in order to decrease the sampling rate. A reference signal generator module is configured and arranged to generate a reference signal with a frequency in response to the decimation rate. A decimation modification module is configured and arranged to modify the decimation rate, in response to an indication of a change in phase difference between the reference signal and the AC, in order to neutralize the phase difference. This can be particularly useful for maintaining a close correlation between transmitted signal frequencies (which vary with AC frequency) and signal processing (which can use an FFT with a frequency-varying sampling rate of CA).
    [021]Other embodiments relate to methods for using one or more circuits of a receiving device. One such method includes converting, using an analog-to-digital converter (CAD), an analog input signal from power distribution lines that carry power using alternating current (AC) into a digital format. This digital input signal can be an over-sampled digital signal, where the digital signal is over-sampled with respect to downstream processing (eg FFT-based processing). One or more processing circuits can then be used to decimate the digital input signal according to a decimation rate. A reference signal can be generated by the processing circuit in response to the decimation rate. The processing circuit can also be used to detect a change in phase difference between the AC and the reference signal and modify the decimation rate, in response to detecting a change in phase difference, in order to neutralize the De-detect change in phase difference.
    [022] More specific embodiments of the present invention refer to a receiver device configured to decode orthogonal carrier frequency channels. For example, orthogonal frequency division multiplexing (OFDM) is a method for encoding digital data into multiple channels of orthogonal carrier frequencies. The orthogonal character of the frequency channels ensures that there is no crossover between the subchannels. For example, an FFT can be constructed for a given set of orthogonal channels and in such a way that each channel is separable in being able to reject components from other channels. Aspects of the present invention recognize that a component of a properly constructed FFT refers to the FFT buffer fill time (e.g., the time represented by a complete set of input samples). By correlating this fill time with the frequency of the channels, the FFT can reduce or eliminate “spectral leakage”, which can be caused by a mismatch in this correlation. In this way, the orthogonal properties of the channels are effectively preserved in the receiver.
    [023] Specific embodiments of the present invention recognize that the mismatch in correlation can occur when the channel cycles (a cycle being represented by a complete period) are not aligned with the length of the fill time. If the timestamp contains a non-integer number of cycles, spectral leakage occurs. The receiver can be configured to use an FFT of a certain size (which size is the total number of samples). The sample rate (fs) represents the number of samples over a period of time (eg samples/second) and therefore the fill time is the FFT size divided by the sample rate. The channel frequency uses the AC frequency as the reference point to generate the carrier frequency channels. The receiver is therefore configured to adjust the fill time, using a sampling rate, in order to maintain the correlation between the fill time and the carrier frequency channels. In specific embodiments, the variable sampling rate corresponds to a resampler/decimator that decreases the sampling rate of an oversampled signal by selecting samples from the oversampled signal at a variable rate. This variable rate can be thought of either as the decimation/resampling rate or as the sampling rate arising from the decimation rate.
    [024] Certain aspects and embodiments of the present invention relate to receiving devices and corresponding methods that can determine an adjustment to the rate of the decimator. For example, specific embodiments recognize that the receiver can determine the amount of adjustment using a feedback loop. The feedback loop is designed to produce an adjustment for mismatches between the decimation rate and the AC frequency, thereby compensating for FFT mismatches with the transmitted channel frequencies. For a given AC frequency, the receiver is able to determine the desired decimation/resampling rate. Therefore, the feedback loop is configured to respond to the AC frequency.
    [025] In specific embodiments of the present invention, a reference signal is generated from the decimation/resampling rate. For example, the frequency of the reference signal can be set according to the decimation rate. More specifically, the frequency of the reference signal is set to generate a reference signal with a frequency corresponding to the desired AC frequency for the decimation rate. The loop filter then determines the fit by comparing the reference signal to the AC signal to produce a fit that compensates for the differences between the two signals. In one embodiment, the comparison includes detecting a relationship/phase difference between the two signals. Specific embodiments recognize that an exact match between the phases is not required (eg zero degree of deviation) as long as the relationship between the phases is constant. As such, the loop filter can use a derivative of the detected phase to calculate the fit based on a rate of change in phase relationship.
    [026] In certain embodiments of the present invention, the frequency of the reference signal is defined as a value that correlates carrier frequencies of virtual channels. Virtual channel carrier frequencies represent frequencies that are compatible with the decimation rate. These virtual channel carrier frequencies would therefore fit uniformly into the FFT using a signal decimated to the decimation rate. The frequency of the reference signal can therefore be defined as a reference frequency that would result in the carrier frequencies of virtual channels if the reference frequency were the actual AC frequency. Therefore, a frequency mismatch between the reference frequency and the AC frequency corresponds to a mismatch between the decimation rate and the actual AC frequency.
    [027] According to various embodiments of the present invention, the power distribution lines that transport energy are given from one or more generating stations (power plants) to residential and commercial sites of customers. Generating stations use AC to transmit power over long distances through power distribution lines. Long-distance transmission can be performed using relatively high electrical voltage. Substations close to customer sites make it possible to lower the high voltage to a lower voltage (eg by using transformers). Power distribution lines carry this lower voltage AC from substations to customer sites. Depending on the distribution network, exact AC voltages and frequencies may vary. For example, electrical voltages are generally in the range of 100 to 240 V (expressed as root mean square of electrical voltage), with two commonly used frequencies being 50 Hz and 60 Hz. distribution can supply customer sites with 120 V and/or with 240 V at 60 Hz.
    [028] FIG. 1 is a block diagram of a power line communication system in which terminals communicate data to collector units in accordance with some embodiments of the present invention. Power line communication system 100 includes a service network in which a plurality of terminals 114 connect (e.g., connect communicatively) to collector units 108 via power distribution lines 116. For example, data may come from energy meters, gas meters and water meters, which are respectively installed in gas and water distribution networks. Furthermore, although the present invention generally refers to terminals 114 as providing consumption measurement data (e.g., energy) through a power distribution network, other data may also be communicated.
    [029]Terminals 114 can be implemented to monitor and advertise various operational characteristics of the service network. For example, in an energy distribution network, meters can monitor characteristics related to energy consumption in the network. Typical examples related to grid power consumption include average or total power consumption, power surges, power outages and load changes, among other characteristics. In gas and water distribution networks, meters can measure similar characteristics related to gas and water consumption (eg total flow and pressure).
    [030]The terminals 114 disclose the operational characteristics of the network through the communication channels. Communication channels are portions of the spectrum through which data is transmitted. The central frequency and bandwidth of each communication channel can depend on the communication system in which they are implemented. In some implementations, communication channels for consumption meters (eg, energy, gas and/or water meters) can be transmitted using power line communication networks that allocate the available bandwidth between terminals according to a orthogonal frequency division multiple access (OFDMA) spectral allocation technique or another channel allocation technique.
    [031] When terminals 114 are implemented in a connected manner to energy meters in a power distribution network, they transmit disclosure data that specifies up-to-date information about the meter which may include measurements of energy consumption, energy consumption by period specified time, peak power consumption, instantaneous electrical voltage, peak electrical voltage, minimum electrical voltage, and other measures related to power consumption and power management (eg, load information). Each of the terminals can also transmit other data, such as status data (for example, operating in normal operating mode, emergency power mode, or another condition such as a crash recovery condition).
    [032] In some implementations, symbols (which represent one or more bits expressing disclosure and/or condition data) are transmitted over power lines 116 for a specific symbol period. A symbol period is a period of time during which each symbol is communicated. Some specific embodiments concern the use of multitonal phase shift modulated (MTPSK) symbols, although it is possible to use other types of modulation scheme. For example, multitonal frequency shift modulated symbols with relative phase (MTFSK with θ) can also be used. For more background details on these symbols, see US Patent Publication No. 20100164615, System And Method For Relative Phase Shift Keying, Application No. 12/347,052, filed December 31, 2008, which is incorporated in its entirety into this document by reference.
    [033] In FIG. 1, terminals 114 transmit symbols to collector units 108, respectively, via communication channels. In certain embodiments, terminals 114 are positioned at customer locations (eg, buildings). Transformers 112 are usually, but not always, positioned close to customer locations. These 112 transformers make it possible to lower the electrical voltage before the AC power is supplied to the customer. Collector units 108 may include a system of circuitry (e.g., with one or more data processors) configured and arranged to communicate with terminals 114 via power distribution lines 116. Collector units 108 may also include a system of circuitry for interfacing with a control center 104. The interface with the control center 104 can be implemented using a number of different communication networks, including, but not limited to, a wide area network (WAN) using Ethernet.
    [034] According to certain embodiments of the present invention, the collectors are installed in distribution substations 106 and used to control bidirectional communication between the control center 104 (for example, located in the service provider's office) and the terminals 114 (eg located at measurement sites on customer sites). In accordance with certain embodiments, the collectors 108 are constructed to an industrial scale computer specification in order to withstand the harsh environment of a substation.
    [035] In certain embodiments of the present invention, the one or more collectors 108 are configured to receive data from different terminals 114 and, at the same time, store them in a database. A collector 108 can also take measurements based on data received from terminals 114 and transmit data received from terminals 114 to a control center 104. For example, in a PLC network, control center 104 can receive data indicative of the control. -energy juice is significantly higher in a specific part of a power grid than in other parts of the power grid. Based on this data, command center 104 allocates additional resources to that specific part of the network (ie, load balancing) or provides data to an operator of power plant 102 (ie, specifying that there is an increase in power consumption. power in that specific part of the power grid).
    [036]According to certain embodiments, the command center 104 provides an interface that allows other devices to access data received from the terminals 114. For example, these user devices may belong to an operator of the service provider, to the staff service provider and/or service provider customers. The data identifying the increase in energy consumption described above can be transmitted to a user device accessible by the operator of system 100, who, in turn, takes an appropriate measure with respect to the increase in consumption. In addition, data identifying a time of use measure and/or a peak demand measure can also be transmitted to user devices. Similarly, in the event of an electrical failure, the control center 104 transmits data to user devices accessible by customers to disclose information about the existence of the electrical failure and, possibly, disclose information estimating its duration.
    [037]The collectors 108 can communicate with the control center 104 through a wide area network (WAN), a local area network (LAN), the Internet or other communication networks. These data networks can be implemented in the form of wired or wireless networks. Wired networks can include any media-restricted networks, including but not limited to networks implemented using magnetic wire conductors, fiber optic materials or waveguides. Wireless networks include outdoor propagation networks, including, but not limited to, networks implemented using outdoor optical networks or radio waves.
    [038]Symbols from a specific terminal can be transmitted through any of thousands of communication channels in the system. For example, each terminal can be allocated to a specific channel using OFDMA or another channel allocation technique. Channel allocations for terminals 114 can be stored, for example, in a communication database accessible to collectors 108.
    [039] According to the embodiments of the present invention, each collector 108 is configured to communicate with thousands of terminals 114, and thousands of collectors 108 can communicate with the command center 104. For example, the same collector can be configured to communicate with over 100,000 terminal devices and a command center can be configured to communicate with over 1,000 collectors. As such, there can be millions of terminals in all and many thousands of these terminals can communicate with the same collector through a shared power distribution line. Thus, some embodiments of the present invention deal with coordinating communications using carefully developed time-based protocols and related considerations.
    [040]For example, collectors 108 can be designed to demodulate transmissions coming from terminal devices 114 in the digital domain using one or more digital signal processors (PSDs). A PSD can include (or receive input from) an analog-to-digital converter (CAD) which produces a digital input signal that includes modulated signals to carry data, where the modulation uses corresponding carrier frequencies. The PSD can demodulate the digital input signal to retrieve the data. Certain embodiments of the present invention are intended to transform the digital input signal into the frequency domain as part of demodulation. More specific embodiments establish this transformation using an FFT. FFT can be performed on a decimated version of the digital input signal, where the decimation rate responds to an AC frequency carried over the power line. Assuming that other FFT parameters, such as the total number of samples, are maintained, a change in the decimation rate results in a change in time between samples. By modifying the time between samples, the FFT input sampling rate is effectively changed to take into account changes in carrier frequencies, which can be caused by changes in the AC frequency.
    [041] FIG. 2 illustrates a block diagram for a collector device in accordance with some embodiments of the present invention. Collector 202 includes a receiver circuit 204 connected to power distribution lines 206. In certain embodiments, receiver circuit 204 also includes transmitter components, i.e., it may be a transceiver. The CAD 208 converts the signal coming from the receiver circuit 204 into a digital format.
    [042]Some aspects of the present invention recognize that while CADs can generate high sampling rates at relatively low cost, the performance of signal processing at high sampling rates can be particularly burdensome. Furthermore, decimation from a high (oversampled) sample rate to a lower sample rate can produce process gains, thus increasing receiver sensitivity. Therefore, a decimator module 212 decreases the signal sampling rate according to a decimation rate. The decimated signal is then sent to a signal processing module 220. In specific implementations, signal processing module 220 uses an FFT as part of signal processing and demodulation. For example, data communications can use orthogonal frequency channels to decrease or eliminate interference between channels. FFT can be designed to preserve the orthogonal character of the channels during transformation when the frequency of the channels is known. For example, the FFT can be designed with an FFT size that ensures the FFT fill time is an integer multiple of the channel periods. If the frequency of a channel changes, then the FFT fill time may no longer be an integer multiple of the channel periods. Thus, various embodiments of the present invention are intended to adjust the filling time, including, for example, adjusting the sampling rate of the samples used to fill the FFT buffer.
    [043] According to certain embodiments of the present invention, the decimator module 212 is configured to operate at a variable decimation rate. In this way, a digital signal coming from a CAD that operates at a sampling rate of N samples/second that is decimated by a varying decimation rate of M produces a signal with a sampling rate of N/M. In specific embodiments, the sample rate N/M is varied so that a defined number of samples, at the sample rate N/M, corresponds to an integer multiple of the channel periods. For example, a symbol period used for the orthogonal channel protocols can be selected such that it is an integer multiple of the channel periods. Therefore, the sample rate N/M is varied to provide a defined number of samples over the symbol period.
    [044]Some aspects of the present invention recognize that as the channel periods are tied to the AC frequency, the decimation rate M can also be tied to the AC frequency. CAD 208 sends the digital signal to phase difference detector 216. A reference signal generator 214 produces a reference signal, which is also sent to phase difference detector 216. In accordance with some embodiments of the present invention, the reference signal generator 214 produces a reference signal with a frequency in response to the decimation rate of the decimator module 212. In more specific embodiments, the frequency of the reference signal corresponds to an AC frequency that would result in coherent channel frequencies. with the rate of the decimator. For example, the transmitting device can generate the channel carrier frequencies based on the actual FCA AC frequency. The desired decimation rate can therefore be determined as a function of the actual FCA. Reference signal generator 214 can reverse this process and determine a desired FCA from the actual decimation rate. When the desired FCA (represented by the reference signal) is compatible with the real FCA, the decimation rate is taken as correct; however, a mismatch between these frequencies would indicate that the actual decimation rate should be adjusted.
    [045]Some aspects of the present invention recognize that the actual FCA does not need to be calculated using a frequency calculation module. Rather, certain embodiments can compare the reference signal to the AC signal to determine a frequency mismatch. More specifically, a phase difference detector module 216 can be used to detect a phase difference between the two signals. This difference is then sent to the decimation (rate) modification module 218.
    [046]Decimation modification module 218 determines an adjustment to the decimation rate. This setting is sent to both the reference signal generator module 214 and the decimator module 212. According to certain embodiments, the decimation modification module 218 is configured to respond to a change in phase difference (e.g., the derivative of phase difference). This can be particularly useful for simplifying the tuning process, as it allows the two signals to be at any phase angle to each other, as long as the frequencies match and the difference in phase difference doesn't change.
    [047] FIG. 3 illustrates another block diagram for a collector device that may be disposed in a distribution substation in accordance with some embodiments of the present invention. Although aspects of the present invention are not limited to a specific power supply standard (for example, they can be applied to standards in different countries and, similarly, to future revisions), power distribution substations lower AC power. transmitted using three phases. In view of this, FIG. 3 illustrates CADs 302 connected to respective phases.
    [048] According to some embodiments of the present invention, the input of the line transformer can be used as input for the electrical voltage of the line, as opposed to the Phase A, Phase B and Phase C inputs, which are inputs of the current transformer used for phase currents. Phases A and B inputs can include communication signals from terminals. Therefore, each phase is monitored and used when receiving communication signals from terminals. The AC power supply component in these three phases, however, depends on substation loading, which can vary significantly. Line voltage, on the other hand, generally has a more stable and predictable AC signal component. Thus, certain embodiments utilize the AC frequency of the line voltage in the control feedback loop.
    [049]Each of the CADs 302 produces a digital output at a high (over)sampled rate. Variable decimators (resamplers) 304 decimate these digital signals at a lower sampling rate. Decimated signals are used by processing modules 308. In certain embodiments, a fixed decimation module 306 is implemented in addition to variable decimators 304.
    [050] The phase detector 310 produces a signal that represents the phase difference between the digital signals coming from the power distribution line and a reference signal produced by the reference generator 316. In a specific embodiment, the generator of Reference 316 is a direct digital synthesizer (SDD). Thus, the phase detector module 310 detects any phase shift between the digitized line electrical voltage and the reference signal. In a specific embodiment, phase shift is detected by multiplying the two input signals together. The results can then be filtered with a 312 filter (eg to remove noise and frequencies above the basic AC frequency). Filter 312 can be any of a number of different filter types, including, but not limited to, different types of low-pass, high-pass, band-reject, and band-pass filters. Filter 312 can be configured and arranged to filter out line harmonics and/or frequency components caused by the signal processing element. For example, the phase detector output contains the sum and difference of the two inputs, so in the case of input components close to 60 Hz, the output will be a slightly varying signal close to DC superimposed by an image close to 120 Hz Other phase sensing circuits are possible, and filter 312 can be configured and arranged accordingly.
    [051] Derivative block 314 determines the rate of change for the output of phase detector 310. In a specific embodiment, derivative block 314 is constructed using a derivative integral proportional (PID) controller module. The specific embodiment of FIG. 3 uses the derivative part of this controller as input to the decimation rate adjustment module 320. The decimation rate adjustment is then used by the sample rate determination module 318 to determine the desired sample rate. The derivative signal represents a phase shift, and if the AC signal and the reference signal have different frequencies, they may have a phase relationship that changes with time. After matching the frequencies, the phase angle/differential can remain relatively constant. Therefore, the decimation rate adjustment module 320 can be configured to produce a decimation rate adjustment that causes an adjustment to the frequency of the reference signal in order to neutralize the changing phase. For example, an increasing phase angle (positive derivative value) can be neutralized with a reduction in the decimation rate. A decreasing phase angle (negative derivative value) can be neutralized with an increase in the decimation rate. This is just an example, and the specific relationship between the phase angle and the rate of decay can be defined with respect to how the phase angle is determined.
    [052]According to embodiments of the present invention, the derivative module 314 operates on a portion of the output signal of loop filter 312 that is close to DC. Therefore, loop filter 312 can be used to remove harmonics and interference (eg parts of the image close to 120 Hz). In a non-limiting example, the loop filter 312 can be implemented in the form of a low-pass filter, such as a 6-pole Butterworth low-pass filter. You can take into account, when selecting the filter, the reduction of the delay of the group together with the increase of the attenuation in the harmonics (120 Hz). For example, a cutoff frequency (eg 27.5 Hz) can be selected to optimize group delay versus attenuation. Specific values, including cutoff frequency, are readily adjustable depending on the specific application.
    [053] According to certain embodiments of the present invention, the amplitude of the line voltage input is prescaled (as well as the reference signal) to produce a loop filter output 312 between -1.0 and +1.0. This effectively normalizes the signal sent to the derivative module. This normalization is particularly useful in applications that use a PID controller module, for example, as it simplifies the loop gain processing.
    [054]Other embodiments concern the use of one of the proportional and integral inputs, or both, of the PID controller module as part of the feedback control loop. The one or more additional outputs can be particularly useful for fast acquisition/locking of AC frequency and/or for improved long-term accuracy. Some aspects of the present invention, however, recognize that the use of the proportional and integral parts of the PID feedback can complicate loop tuning and sometimes increase instability.
    [055]In one embodiment, the output of decimation rate adjustment module 320 is determined by multiplying the output of derivative module 314 by a gain factor. Other involved algorithms can also be used as desired.
    [056] In a specific example and experimental embodiment, the frequency reference signal is controlled by varying its sampling rate, but regardless of the output frequency, the 316 frequency signal generator always produces the same defined number of cycles in a defined number of samples. This results in the same number of input samples for the FFTs in the defined number of cycles. More specifically, the same decimation rate that drives the sampling rate for the 316 reference signal generator also drives the sampling rate for the decimation (resampling) of Phase A, Phase B, and Phase C by variable decimator modules 304 For example, the AC frequency that tracks the resampling rate can be represented by the algorithm A/((A * G * H) / (D * E * actual AC frequency)), where: A = sampling rate ( crystal-based) of the digital input signal; D = fixed decimation rate; E = number of FFT input samples; G = symbol period; and H = AC nominal frequency. Several different values can be selected as appropriate to the applications (eg with respect to processor throughput, available memory and/or communication bandwidth). An ideal solution for a given application can also be based on transmitter power, channel noise and desired bit error rate. These factors can be particularly relevant for selecting a symbol period and the related number of reference SDD output cycles per symbol period.
    [057]The signals and the associated logic and functionality described with respect to the figures can be implemented in several different ways. Unless otherwise indicated, various general purpose systems and/or logic circuit systems can be used with programs in accordance with the teachings of this document, or it may prove convenient to build more specialized apparatus to carry out the desired method. For example, in accordance with the present invention, one or more of the methods may be implemented in a system of physically connected circuits by programming a general purpose processor, other systems of fully programmable or semi-programmable logic circuits, and/or a combination hardware with a general purpose processor configured with software. Thus, the various components and processes illustrated in the figures can be implemented in a variety of circuit-based ways, such as through the use of data processing circuit modules.
    [058] It is clear that some aspects of the invention can be practiced with computer/processor-based system configurations other than those expressly described in this document. The structure required for a variety of these systems and circuits will show in light of the intended application and description above.
    [059]The various terms and techniques are used by those skilled in the art to describe aspects associated with one or more communications, protocols, applications, implementations and mechanisms. One of these techniques is to describe the implementation of a technique expressed in terms of an algorithm or mathematical expression. Although these techniques can be implemented, for example, by running code on a computer, the expression of these techniques can be transmitted and communicated as a formula, algorithm or mathematical expression.
    [060]For example, the block that indicates "C=A+B" as an additive function whose implementation in hardware and/or software would take two inputs (A and B) and produce a summation output (C), as in a system of combinatorial logic circuits. Therefore, the use of formulas, algorithms or mathematical expressions as descriptions should be understood as having a physical embodiment in at least one hardware (such as a processor on which the techniques of the present invention can be practiced, as well as implemented in the form of a implementation).
    [061] In certain embodiments, machine-executable instructions are stored for execution in a manner consistent with one or more of the methods of the present invention. Instructions can be used to have a general or specific purpose processor programmed with instructions to perform the method steps. Steps can be performed by specific hardware components that contain hard-wired logic to perform the steps, or by any combination of programmed computer components and custom hardware components.
    [062] In some embodiments, certain aspects of the present invention may be offered in the form of a computer program product, which may include a machine or computer readable medium with stored instructions that can be used to program a computer ( or other electronic devices) to carry out a process according to the present invention. Therefore, computer readable medium includes any type of machine readable medium/media suitable for storing electronic instructions.
    [063] The various embodiments described above are given by way of illustration and are not to be construed to necessarily limit the invention. Based on the above discussion and illustrations, those skilled in the art will appreciate that various modifications and changes can be made to the present invention without strictly following the exemplary embodiments and applications illustrated and described herein. For example, these changes may include variations to specific circuitry and/or software code to implement one or more of the various modules. Such modifications and changes do not depart from the true essence and scope of the present invention, including aspects set out in the following claims.
    权利要求:
    Claims (18)
    [0001]
    1. Circuit-based apparatus comprising: a transceiver circuit (204) configured and arranged to communicate through power distribution lines (116) that carry power using alternating current (AC); processing configured and arranged to provide: an analog-to-digital converter (CAD) module, configured to generate a digital input signal from an analog signal that was received in the transceiver circuit (204); a decimator module (212) configured to produce, in response to a variable decimation rate, a decimated digital input signal; a reference signal generator module (214) configured to generate a reference signal with a frequency in response to the decimation rate; and a decimation modification module (218), configured and arranged to modify, in response to an indication of a change in a phase difference between the reference signal and the AC, the rate of decimation to neutralize the phase difference.
    [0002]
    2. Circuit-based apparatus, according to claim 1, CHARACTERIZED by the fact that the reference signal generator module (214) is configured and arranged to generate the reference signal using a direct digital synthesizer (SDD).
    [0003]
    3. Circuit-based apparatus, according to claim 1, CHARACTERIZED by the fact that the decimator module (212) is configured and arranged to set the decimation rate on a fixed number of FFT input samples for each CA period.
    [0004]
    4. Circuit-based apparatus according to claim 1, CHARACTERIZED by the fact that the decimation modification module (218) is configured and arranged to set the decimation rate on a fixed number of FFT input samples to each symbol transmitted.
    [0005]
    The circuit-based apparatus of claim 1, further including a signal processing module (220) configured and arranged to demodulate the decimated digital input signal.
    [0006]
    Circuit-based apparatus according to claim 1, CHARACTERIZED by further including a signal processing module (220) configured and arranged to demodulate the decimated digital input signal according to a multiple access spectral allocation technique by orthogonal frequency division (OFDMA).
    [0007]
    7. Circuit-based apparatus, according to claim 1, CHARACTERIZED by the fact that the one or more processing circuits are configured and further arranged to provide modules in parallel for several channels with different carrier frequencies.
    [0008]
    8. Circuit-based apparatus according to claim 1, CHARACTERIZED by the fact that the one or more processing circuits are configured and further arranged to provide a derivative module (314) configured and arranged to produce the change indication in a phase difference between the reference signal and the AC.
    [0009]
    9. Circuit-based apparatus, according to claim 1, CHARACTERIZED by the fact that the one or more processing circuits are configured and further arranged to provide a derivative integral proportional controller module (PID) and in which the module PID controller is configured and arranged to produce the indication of change in a phase difference between the reference signal and the AC.
    [0010]
    10. Circuit-based apparatus, according to claim 1, CHARACTERIZED by the fact that the one or more processing circuits are configured and further arranged to provide a fixed decimation module that decimates the digital input signal according to a fixed decimation rate.
    [0011]
    11. Method CHARACTERIZED by comprising: converting, using an analog-to-digital converter (CAD), an analog input signal coming from power distribution lines (116) that transport energy using alternating current (AC) to a digital format; processing circuit to: decimate the digital input signal according to a decimation rate; generate a reference signal in response to the decimation rate; detect a change in a phase difference between the AC and the reference signal; and modify, in response to detecting a change in phase difference, the decimation rate to counteract the detected change in phase difference.
    [0012]
    12. The method according to claim 11, CHARACTERIZED in that using a processing circuit to decimate the digital input signal includes producing a decimated signal having a sampling rate that takes into account frequency changes at frequencies carrying the channels that are caused by corresponding changes in an AC frequency.
    [0013]
    13. Method according to claim 11, characterized in that using a processing circuit further includes detecting a change in a phase difference by multiplying a digital input signal decimated with the reference signal.
    [0014]
    14. Method according to claim 11, CHARACTERIZED by the fact that using a processing circuit further includes detecting the change in phase difference by multiplying a digital input signal decimated with the reference signal and applying a filter to an output of the multiplication.
    [0015]
    15. Method according to claim 11, CHARACTERIZED in that using a processing circuit further includes generating the reference signal by setting a frequency of the reference signal to a value that correlates virtual channel carrier frequencies to the frequency of the reference signal with the decimation rate.
    [0016]
    16. The method according to claim 11, CHARACTERIZED by the fact that using a processing circuit further includes demodulating symbols modulated according to one of multitonal phase shift modulation (MTPSK) and multitonal frequency shift modulation ( MTFSK) and where the demodulation uses the decimated digital input signal.
    [0017]
    17. The method according to claim 11, CHARACTERIZED by the fact that using a processing circuit further includes demodulating the decimated digital input signal according to an orthogonal frequency division multiple access (OFDMA) spectral allocation technique.
    [0018]
    18. Method according to claim 11, CHARACTERIZED by the fact that using a processing circuit further includes modifying the decimation rate to neutralize spectral leakage due to a mismatch in an FFT fill time and channel carrier frequencies .
    类似技术:
    公开号 | 公开日 | 专利标题
    BR112014015159B1|2021-08-24|DIGITAL SIGNAL PROCESSING APPARATUS AND METHOD FOR PLC COMMUNICATIONS WITH COMMUNICATION FREQUENCIES
    CN103543335B|2016-04-20|A kind of synchronous phasor measuring method
    EP3213094B1|2020-06-24|System, method and apparatus for grid location
    JP5778979B2|2015-09-16|Wattmeter phase identification
    US9214985B2|2015-12-15|Coordinating power distribution line communications
    RO130020A2|2015-01-30|Receiver for powerline carrier communication
    WO2003093846A1|2003-11-13|Measurement device and measurement method
    US9995774B2|2018-06-12|Frequency estimation
    CN103460059B|2015-11-25|A kind of power-measuring device
    US20180292447A1|2018-10-11|Floating Neutral Detection and Localization System and Methods
    JP2013009556A|2013-01-10|Voltage sensitivity measurement system, power device control system, terminal device, information processing device, and method and program of the same
    BR112013027100B1|2022-01-11|SYSTEM AND METHOD PERFORMED BY DATA PROCESSING APPARATUS TO COMMUNICATE DATA THROUGH AN ELECTRIC POWER NETWORK
    WO2014090450A1|2014-06-19|Estimating an electricity supply's fundamental frequency
    WO2018191436A1|2018-10-18|Floating neutral detection and localization system and methods
    Artale et al.2021|Implementation of a PLC Field Analyzer on a G3 Modem Platform
    CN203396937U|2014-01-15|Voltage-transformer secondary voltage detection system applied in power field
    Bebongchu2013|Current Modulation for Data Transmission on Power Lines
    同族专利:
    公开号 | 公开日
    CA2860154A1|2013-06-27|
    MX336334B|2016-01-15|
    BR112014015159A2|2017-06-13|
    US20140314161A1|2014-10-23|
    SE1450903A1|2014-07-18|
    WO2013096134A1|2013-06-27|
    US8737555B2|2014-05-27|
    RO130016A2|2015-01-30|
    US9503157B2|2016-11-22|
    CA2860154C|2018-05-22|
    MX2014007440A|2014-08-01|
    SE542283C2|2020-04-07|
    US20130163644A1|2013-06-27|
    引用文献:
    公开号 | 申请日 | 公开日 | 申请人 | 专利标题
    US5146473A|1989-08-14|1992-09-08|International Mobile Machines Corporation|Subscriber unit for wireless digital subscriber communication system|
    US5581229A|1990-12-19|1996-12-03|Hunt Technologies, Inc.|Communication system for a power distribution line|
    US5535240A|1993-10-29|1996-07-09|Airnet Communications Corporation|Transceiver apparatus employing wideband FFT channelizer and inverse FFT combiner for multichannel communication network|
    US6437692B1|1998-06-22|2002-08-20|Statsignal Systems, Inc.|System and method for monitoring and controlling remote devices|
    US6154488A|1997-09-23|2000-11-28|Hunt Technologies, Inc.|Low frequency bilateral communication over distributed power lines|
    US6836737B2|2000-08-09|2004-12-28|Statsignal Systems, Inc.|Systems and methods for providing remote monitoring of consumption for a utility meter|
    US6341148B1|1998-11-04|2002-01-22|Level One Communications, Inc.|Method and apparatus for minimizing transient sampling fluctuations upon transition between modes of communication|
    US6177884B1|1998-11-12|2001-01-23|Hunt Technologies, Inc.|Integrated power line metering and communication method and apparatus|
    US7346463B2|2001-08-09|2008-03-18|Hunt Technologies, Llc|System for controlling electrically-powered devices in an electrical network|
    US6965502B2|2001-03-21|2005-11-15|Primarion, Inc.|System, device and method for providing voltage regulation to a microelectronic device|
    US20030133473A1|2001-08-04|2003-07-17|Manis Constantine N.|Power line communication system|
    US20030036810A1|2001-08-15|2003-02-20|Petite Thomas D.|System and method for controlling generation over an integrated wireless network|
    US7102490B2|2003-07-24|2006-09-05|Hunt Technologies, Inc.|Endpoint transmitter and power generation system|
    US7236765B2|2003-07-24|2007-06-26|Hunt Technologies, Inc.|Data communication over power lines|
    US7180412B2|2003-07-24|2007-02-20|Hunt Technologies, Inc.|Power line communication system having time server|
    US7145438B2|2003-07-24|2006-12-05|Hunt Technologies, Inc.|Endpoint event processing system|
    US6998963B2|2003-07-24|2006-02-14|Hunt Technologies, Inc.|Endpoint receiver system|
    US7742393B2|2003-07-24|2010-06-22|Hunt Technologies, Inc.|Locating endpoints in a power line communication system|
    US20050169415A1|2004-01-30|2005-08-04|Agere Systems Inc.|Timing error recovery system|
    US7443313B2|2005-03-04|2008-10-28|Hunt Technologies, Inc.|Water utility meter transceiver|
    US7706320B2|2005-10-28|2010-04-27|Hunt Technologies, Llc|Mesh based/tower based network|
    US7904034B2|2006-12-18|2011-03-08|Samsung Electronics Co., Ltd.|Method and system for providing an interference cancellation in a wireless communication system|
    US7792220B2|2006-12-19|2010-09-07|Sigmatel, Inc.|Demodulator system and method|
    BRPI0807962A2|2007-03-01|2017-05-30|Hunt Tech Llc|signal interruption detection|
    WO2008154365A1|2007-06-06|2008-12-18|Hunt Technologies, Llc.|Dsp workload distribution in a power line carrier system|
    SE535727C2|2007-10-26|2012-11-27|Damian Bonicatto|Programmable signal splitter|
    US8194789B2|2007-12-05|2012-06-05|Hunt Technologies, Llc|Input signal combiner system and method|
    JP5654198B2|2008-06-16|2015-01-14|日立アロカメディカル株式会社|Ultrasonic diagnostic equipment|
    WO2010008492A1|2008-06-25|2010-01-21|Ikanos Communications, Inc.|Method and apparatus for a multi-tone modem|
    US8165255B2|2008-12-19|2012-04-24|Freescale Semiconductor, Inc.|Multirate resampling and filtering system and method|
    US8144820B2|2008-12-31|2012-03-27|Hunt Technologies, Llc|System and method for relative phase shift keying|
    US8238263B2|2009-03-18|2012-08-07|Landis+Gyr Technologies, Llc|Network status detection|
    US8666355B2|2010-01-15|2014-03-04|Landis+Gyr Technologies, Llc|Network event detection|
    US9037305B2|2010-03-02|2015-05-19|Landis+Gyr Technologies, Llc|Power outage verification|
    US8681619B2|2010-04-08|2014-03-25|Landis+Gyr Technologies, Llc|Dynamic modulation selection|
    US8325728B2|2010-09-07|2012-12-04|Landis+Gyr Technologies, Llc|Dynamic data routing in a utility communications network|
    US8675779B2|2010-09-28|2014-03-18|Landis+Gyr Technologies, Llc|Harmonic transmission of data|
    US20120084559A1|2010-09-30|2012-04-05|Hunt Technologies, Llc|Communications Source Authentication|
    JP5582954B2|2010-10-12|2014-09-03|ルネサスエレクトロニクス株式会社|DIGITAL PLL CIRCUIT, INFORMATION REPRODUCING DEVICE, DISC REPRODUCING DEVICE, AND SIGNAL PROCESSING METHOD|
    US8731076B2|2010-11-01|2014-05-20|Landis+Gyr Technologies, Llc|Variable symbol period assignment and detection|CA2870452C|2011-04-15|2020-03-10|Dominion Energy Technologies, Inc.|System and method for single and multi zonal optimization of utility services delivery and utilization|
    CA2874132A1|2011-06-09|2013-01-17|Dominion Energy Technologies, Inc.|System and method for grid based cyber security|
    US9380545B2|2011-08-03|2016-06-28|Astrolink International Llc|System and methods for synchronizing edge devices on channels without carrier sense|
    US10097240B2|2013-02-19|2018-10-09|Astrolink International, Llc|System and method for inferring schematic and topological properties of an electrical distribution grid|
    US9438312B2|2013-06-06|2016-09-06|Astrolink International Llc|System and method for inferring schematic relationships between load points and service transformers|
    MX357831B|2013-06-13|2018-07-26|Astrolink Int Llc|Non-technical losses in a power distribution grid.|
    CN105453448A|2013-06-13|2016-03-30|艾斯通林克国际有限责任公司|Inferring feeder and phase powering a transmitter|
    US9509371B2|2013-09-19|2016-11-29|Enphase Energy, Inc.|Method and apparatus for power line communications distortion compensation|
    AU2015338896B2|2014-10-30|2020-11-12|Dominion Energy Technologies, Inc.|System, method and apparatus for grid location|
    AU2015338943B2|2014-10-30|2019-09-12|Dominion Energy Technologies, Inc.|System and methods for assigning slots and resolving slot conflicts in an electrical distribution grid|
    CN105551227A|2015-12-10|2016-05-04|国网四川省电力公司电力科学研究院|Waveform signal source directly injected into power line|
    US9893795B1|2016-12-07|2018-02-13|At&T Intellectual Property I, Lp|Method and repeater for broadband distribution|
    US10715886B2|2017-06-06|2020-07-14|Landis+Gyr Technologies, Llc|Power outage-assessment apparatuses and methods|
    US10270491B2|2017-08-31|2019-04-23|Landis+Gyr Technologies, Llc|Power-line communication systems AMD methods having location-extendable collector for end-point data|
    US10516421B1|2017-09-19|2019-12-24|Landis+Gyr Technologies, Llc|Apparatuses and methods involving radio configurability for adapting to radio-frequency systems|
    US10502764B2|2018-01-05|2019-12-10|Rohde & Schwarz Gmbh & Co. Kg|Signal analyzing circuit and method for auto setting an oscilloscope|
    CN108600141A|2018-03-09|2018-09-28|北京宇电科技集团有限公司|Using the power carrier communication system of OFDM|
    US10340980B1|2018-05-07|2019-07-02|Landis+Gyr Technologies, Llc|Time synchronization apparatuses and methods for power-distribution systems and the like|
    法律状态:
    2018-12-04| B06F| Objections, documents and/or translations needed after an examination request according [chapter 6.6 patent gazette]|
    2019-11-05| B06U| Preliminary requirement: requests with searches performed by other patent offices: procedure suspended [chapter 6.21 patent gazette]|
    2021-03-09| B07A| Application suspended after technical examination (opinion) [chapter 7.1 patent gazette]|
    2021-06-01| B350| Update of information on the portal [chapter 15.35 patent gazette]|
    2021-07-06| B09A| Decision: intention to grant [chapter 9.1 patent gazette]|
    2021-08-24| B16A| Patent or certificate of addition of invention granted [chapter 16.1 patent gazette]|Free format text: PRAZO DE VALIDADE: 20 (VINTE) ANOS CONTADOS A PARTIR DE 14/12/2012, OBSERVADAS AS CONDICOES LEGAIS. |
    优先权:
    申请号 | 申请日 | 专利标题
    US13/334,522|2011-12-22|
    US13/334,522|US8737555B2|2011-12-22|2011-12-22|Digital signal processing for PLC communications having communication frequencies|
    PCT/US2012/069898|WO2013096134A1|2011-12-22|2012-12-14|Digital signal processing for plc communications having communication frequencies|
    [返回顶部]