A very narrow band multipoint communication system suitable for use in an automatic meter reading (AMR) system having a communication protocol that divides each main channel of a frequency or digital code hopping system into multiple sub-channels and applies frequency division multiplexing among the
A very narrow band multipoint communication system suitable for use in an automatic meter reading (AMR) system having a communication protocol that divides each main channel of a frequency or digital code hopping system into multiple sub-channels and applies frequency division multiplexing among the sub-channels. Each sub-channel exhibits a very narrow band characteristic that allows gain increase to increase the transmission range of the meters. In addition, frequency division multiplexing among the sub-channels greatly increases the number of meters that can communicate on each main channel. The data collection device demodulates and decodes the multiplexed meter signals at an intermediate frequency with electronic circuitry. The resulting very narrow band AMR system exhibits greater transmission range, greater bandwidth and can accommodate a much larger number of meters per data collection device in comparison to a conventional narrow band AMR system.
대표청구항▼
The invention claimed is: 1. An automatic meter reading system, comprising: a plurality of geographically distributed meters; each meter comprising a transmitter for transmitting communication signals comprising meter data via a communication protocol; at least one data collection device configured
The invention claimed is: 1. An automatic meter reading system, comprising: a plurality of geographically distributed meters; each meter comprising a transmitter for transmitting communication signals comprising meter data via a communication protocol; at least one data collection device configured to receive the communication signals from the meters pursuant to the communication protocol; wherein the communication protocol comprises an operational frequency band divided into a plurality of main channels and application of an interference limiting hopping technique among the main channels; wherein each main channel is divided into a plurality of very narrow band sub-channels with frequency division multiplexing among the sub-channels; wherein the meters comprise hop meters and mesh meters, wherein the mesh meters communicate associated data to the hop meters, and the hop meters communicate associated data and the data received from the mesh meters to the data collection device; and wherein each hop meter is configured to communicate with one or more mesh meters via narrow band channels that are substantially wider than the very narrow band sub-channels used for communications between the hop meter and the data collection device. 2. The automatic meter reading system of claim 1, wherein the interference limiting hopping technique comprises frequency hopping. 3. The automatic meter reading system of claim 1, wherein the interference limiting hopping technique comprises digital code hopping. 4. The automatic meter reading system of claim 1, wherein each meter is configured to engage in bidirectional communications with the data collection device. 5. The automatic meter reading system of claim 1, wherein communications from the data collection device to the meters implement channel synchronization for the interference limiting hopping technique of the communication protocol, and communications from the meters to the data collection device deliver the meter data to the data collection device pursuant to the communication protocol. 6. The automatic meter reading system of claim 1, wherein the data collection device down-converts the communication signals from the operational frequency band to an intermediate frequency band, samples the intermediate frequency band to obtain digital representations of the communication signals, and digitally processes the digital representations of the communication signals to demodulate the communication signals and decode the frequency division multiplexing among the sub-channels. 7. The automatic meter reading system of claim 6, wherein the processing of the digital representations of the communication signals comprises application of an FFT algorithm. 8. The automatic meter reading system of claim 1, wherein each meter communicates its associated meter data directly to the data collection device. 9. A very narrow band communication system, comprising: a plurality of geographically distributed transmitters; each transmitter configured for transmitting communication signals via a communication protocol; at least one data collection device configured to receive the communication signals from the transmitters pursuant to the communication protocol; wherein the communication protocol comprises an operational frequency band divided into a plurality of main channels and application of an interference limiting hopping technique among the main channels; wherein each main channel is divided into a plurality of very narrow band sub-channels with frequency division multiplexing among the sub-channels; wherein the transmitters comprise hop transmitters and mesh transmitters, wherein the mesh transmitters communicate associated data to the hop transmitters, and the hop transmitters communicate associated data and the data received from the mesh transmitters to the data collection device; and wherein each hop transmitter is configured to communicate with one or more mesh transmitters via narrow band channels that are substantially wider than the very narrow band sub-channels used for communications between the hop transmitters and the data collection device. 10. The very narrow band communication system of claim 9, wherein the interference limiting hopping technique comprises frequency hopping. 11. The very narrow band communication system of claim 9, wherein the interference limiting hopping technique comprises digital code hopping. 12. The very narrow band communication system of claim 9, wherein each transmitter is configured as a transponder configured to engage in bidirectional communications with the data collection device. 13. The very narrow band communication system of claim 12, wherein communications from the data collection device to the transponders implement channel synchronization for the interference limiting hopping technique of the communication protocol, and communications from the transponders to the data collection device deliver data from the transponders to the data collection device pursuant to the communication protocol. 14. The very narrow band communication system of claim 9, wherein the data collection device down-converts the communication signals from the operational frequency band to an intermediate frequency band, samples the intermediate frequency band to obtain digital representations of the communication signals, and digitally processes the digital representations of the communication signals to demodulate the communication signals and decode the frequency division multiplexing among the sub-channels. 15. The very narrow band communication system of claim 14, wherein the processing of the digital representations of the communication signals comprises application of an FFT algorithm. 16. The very narrow band communication system of claim 9, wherein each transmitter communicates associated data directly to the data collection device. 17. The very narrowband communication system of claim 9, further configured for dynamically assigning a meter to function as hop meter and to dynamically assign one or more mesh meters to communicate with the dynamically assigned hop meter based on signal conditions affecting the dynamically assigned meters.
Gelvin, David C.; Girod, Lewis D.; Kaiser, William J.; Merrill, William M.; Newberg, Fredric; Pottie, Gregory J.; Sipos, Anton I.; Vardhan, Sandeep, Method and apparatus for internetworked wireless integrated network sensor (WINS) nodes.
※ AI-Helper는 부적절한 답변을 할 수 있습니다.