IPC분류정보
국가/구분 |
United States(US) Patent
등록
|
국제특허분류(IPC7판) |
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출원번호 |
UP-0900905
(2007-09-13)
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등록번호 |
US-7764714
(2010-08-13)
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발명자
/ 주소 |
- Monier, Fabrice
- Picard, Gilles
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출원인 / 주소 |
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대리인 / 주소 |
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인용정보 |
피인용 횟수 :
14 인용 특허 :
97 |
초록
▼
The present technology relates to protocols relative to utility meters associated with an open operational framework. More particularly, the present subject matter relates to protocol subject matter for advanced metering infrastructure, adaptable to various international standards, while economicall
The present technology relates to protocols relative to utility meters associated with an open operational framework. More particularly, the present subject matter relates to protocol subject matter for advanced metering infrastructure, adaptable to various international standards, while economically supporting a 2-way mesh network solution in a wireless environment, such as for operating in a residential electricity meter field. The present subject matter supports meters within an ANSI standard C12.22/C12.19 system while economically supporting a 2-way mesh network solution in a wireless environment, such as for operating in a residential electricity meter field, all to permit cell-based adaptive insertion of C12.22 meters within an open framework. Cell isolation is provided through quasi-orthogonal sequences in a frequency hopping network. Additional features relate to apparatus and methodology subject matters relating to crystal drift compensation in a mesh network.
대표청구항
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What is claimed is: 1. A method for compensating for drift in node device clocks in an advanced metering system mesh network, comprising: establishing a network including at least one root node and a plurality of node devices, with at least some of the node devices comprising metrology devices; con
What is claimed is: 1. A method for compensating for drift in node device clocks in an advanced metering system mesh network, comprising: establishing a network including at least one root node and a plurality of node devices, with at least some of the node devices comprising metrology devices; configuring the network for bi-directional communications among the at least one root node and each of the plurality of node devices; providing each node device with a crystal controlled internal clock; conducting packet communications among the root node and the plurality of node devices; and configuring each node device to realign its internal clock each time the node device communicates with another node device closer to the root node than itself, whereby each node device will realign its clock to be in synchronization with the network thereby compensating for time differences caused by drift in any of the node device clocks. 2. A method as in claim 1, further comprising: averaging the amounts of node clock realignments over time for a respective node device; processing the averaged amounts of node clock realignments to determine how fast the node device clock is running for the respective node device; and adjusting the node device clock to bring it into alignment with the network. 3. A method as in claim 2, further comprising: processing the averaged amounts of node clock realignments with respect to the average clock of two or more node devices closer to the root node, whereby compensation is provided for multiple synchronization paths to plural node devices closer to the root node, and for slow drift due to the difference between the crystal frequency of the node device and average crystal frequency in the node devices closer to the root node. 4. A method as in claim 3, further comprising: filtering consecutive clock realignment corrections using a low-pass filter; and adjusting the clock of a node device in accordance with the filtered realignment corrections independently of a resynchronization event, whereby drift is anticipated and compensated without waiting for the next resynchronization. 5. A method as in claim 4, further comprising: recording the value of a node device clock correction; recording the time the correction occurred; and evaluating the crystal drift of the clock of the node device according to the relationship: Xdrift ( n ) = ∑ k = k ( n - 1 ) + 1 k ( n ) Clock_Correction ( k ) Resync_Time ( k ( n ) ) - Resync_Time ( k ( n - 1 ) ) , where Clock_Correction(k) corresponds to the recorded value of the correction at the time of resynchronization k, Resync_time(k(n)) corresponds to the time the resynchronization occurred, and Resync_time(k(−1n)) corresponds to the time the previous resynchronization occurred. 6. A method as in claim 5, further comprising: defining the low-pass filter according to the relationship: Xdrift—filt(n)=A×Xdrift(n)+B×Xdrift—filt(n−1), where Xdrift_filt(n) is filtered crystal drift estimation and A,B are filter coefficients. 7. A method as in claim 6, further comprising: providing a leap time slot count down timer; and introducing a leap time slot according to the pseudo-code: If Time_Slot_Number = 0 (modulo MAC_Xdrift_LeapTS) Then Count_Down_Timer MAC_TS_Length + MAC_Xdrift_LeapTS * ΔTslot Else Count_Down_Timer MAC_TS_Length End where MAC_Xdrift_LeapTS is the interval between leap time slots, MAC_TS_Length is the length of a MAC layer time slot, TS_Length is the length of a time slot, Time_Slot_Number is a number starting from 0 and incremented at each time slot and ΔTslot is defined by the relationship: ΔTslot(n)=ΔTslot(n−1)+TS_Length×Xdrift—filt(n), for each instance n. 8. A method for compensating for crystal frequency drift in an advanced metering system mesh network, comprising: establishing a network including at least one root node and a plurality of node devices, with at least some of the node devices comprising metrology devices; configuring the network for bi-directional communications among the at least one root node and each of the plurality of node devices; providing each of the plurality of node devices with a crystal controlled internal clock; conducting communications among the root node and the plurality of node devices using a repeating hyperframe subdivided into a repeating time slot packet protocol; and configuring each node device to resynchronize its internal clock each time the node device communicates with the root node or another node closer than itself to the root node, whereby the node device will realign its internal clock to be in synchronization with the network, thereby compensating for crystal frequency drift. 9. A method as in claim 8, further comprising: recording individual amounts by which a node device adjusts its internal clock; recording the times the adjustments occurred; evaluating the crystal frequency drift of the clock of the node device according to the relationship: Xdrift ( n ) = ∑ k = k ( n - 1 ) + 1 k ( n ) Clock_Correction ( k ) Resync_Time ( k ( n ) ) - Resync_Time ( k ( n - 1 ) ) , where Clock_Correction(k) corresponds to the recorded amount of the correction at the time of resynchronization k, Resync_time(k(n)) corresponds to the time the resynchronization occurred, and Resync_time(k(−1n)) corresponds to the time the previous resynchronization occurred; and configuring each node device to align its internal clock based on the crystal frequency drift. 10. A method as in claim 9, further comprising: averaging the amounts by which a respective node device adjusts its internal clock over time; processing the averaged amounts to determine how fast the clock of the respective node device is running; and configuring each node device to adjust its internal clock based on the average to bring it into alignment with the network. 11. A method as in claim 10, further comprising processing the averaged amounts based on the averaged clocks of two or more node devices closer to the root node than the respective node device. 12. A method as in claim 11, further comprising: low-pass filtering consecutive amounts by which a respective node device adjusts its internal clock; and adjusting the clock of the respective node device in accordance with the filtered amounts, whereby crystal drift is anticipated and compensated independently from a resynchronization event. 13. A method as in claim 12, further comprising: defining the low-pass filter according to the relationship: Xdrift—filt(n)=A×Xdrift(n)+B×Xdrift—filt(n−1), where Xdrift_filt(n) is filtered crystal drift estimation and A,B are filter coefficients. 14. A method as in claim 13, further comprising: providing a leap time slot count down timer; and introducing a leap time slot according to the pseudo-code: If Time_Slot_Number = 0 (modulo MAC_Xdrift_LeapTS) Then Count_Down_Timer MAC_TS_Length + MAC_Xdrift_LeapTS * ΔTslot Else Count_Down_Timer MAC_TS_Length End where MAC_Xdrift_LeapTS is the interval between leap time slots, MAC_TS_Length is the length of a MAC layer time slot, TS_Length is the length of a time slot, Time_Slot_Number is a number starting from 0 and incremented at each time slot and ΔTslot is defined by the relationship: ΔTslot(n)=ΔTslot(n−1)+TS_Length×Xdrift—filt(n), for each instance n. 15. An advanced metering system mesh network, comprising: at least one root node; a plurality of node devices, with at least some of the node devices comprising metrology devices, said plurality of node devices configured for bi-directional communications among the at least one root node and others of said plurality of node devices using a repeating hyperframe subdivided into a repeating time slot sequence packet protocol; and a plurality of crystal controlled internal clocks, respectively associated with each of said plurality of node devices, wherein each of said node devices is configured to resynchronize its respective internal clock each time each respective node device communicates with said at least one root node or another node device closer than itself to the at least one root node, whereby the respective node device will realign its internal clock to be in synchronization with the network, thereby compensating for crystal frequency drift. 16. A network as in claim 15, wherein each of said node devices is further configured to respectively record individual amounts by which it adjusts its respective internal clock and the times the adjustments occurred, and to evaluate drift in the frequency of the crystal frequency drift associated with the respective clock of the respective node device and to align its respective internal clock according to the relationship: Xdrift ( n ) = ∑ k = k ( n - 1 ) + 1 k ( n ) Clock_Correction ( k ) Resync_Time ( k ( n ) ) - Resync_Time ( k ( n - 1 ) ) , where Clock_Correction(k) corresponds to the recorded amount of the correction at the time of resynchronization k, Resync_time(k(n)) corresponds to the time the resynchronization occurred, and Resync_time(k(−1n)) corresponds to the time the previous resynchronization occurred. 17. A network as in claim 16, wherein each of said node devices is further configured for averaging the amounts by which it adjusts its respective internal clock over time, for processing the averaged amounts to determine how fast its respective clock is running, and for adjusting its respective internal clock based on the average to bring it respective clock into alignment with the network. 18. A network as in claim 17, wherein each of said node devices is further configured to process the averaged amounts based on the averaged clocks of two or more node devices closer than itself to said at least one root node. 19. A network as in claim 18, further comprising: a plurality of low-pass filters, respectively associated with each of said node devices, each respective low-pass filter configured to operate according to the relationship: Xdrift—filt(n)=A×Xdrift(n)+B×Xdrift—filt(n−1), where Xdrift_filt(n) is filtered crystal drift estimation and A,B are filter coefficients, wherein each of said node devices is further configured to low-pass filter consecutive amounts by which it adjusts its respective internal clock and to adjust its respective clock in accordance with the filtered amounts, whereby crystal drift is anticipated and compensated independently from a resynchronization event. 20. A network as in claim 19, further comprising: a plurality of leap time slot count down timers, respectively associated with each of said node devices, wherein each respective node device is further configured to introduce a leap time slot into its repeating time slot sequence according to the pseudo-code: If Time_Slot_Number = 0 (modulo MAC_Xdrift_LeapTS) Then Count_Down_Timer MAC_TS_Length + MAC_Xdrift_LeapTS * ΔTslot Else Count_Down_Timer MAC_TS_Length End where MAC_Xdrift_LeapTS is the interval between leap time slots, MAC_TS_Length is the length of a MAC layer time slot, TS_Length is the length of a time slot, Time_Slot_Number is a number starting from 0 and incremented at each time slot and ΔTslot is defined by the relationship: ΔTslot(n)=ΔTslot(n−1)+TS_Length×Xdrift—filt(n), for each instance n. 21. A network as in claim 15, wherein the at least one root node comprises a cell relay.
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