Cable communication system optical nodes having selectable attenuation values to mitigate distortion of upstream information
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
H04N-007/173
H04B-010/2575
H04L-012/28
H04N-021/61
H04J-014/08
출원번호
US-0593811
(2015-01-09)
등록번호
US-9660729
(2017-05-23)
발명자
/ 주소
Totten, Ronald
West, Lamar
출원인 / 주소
CertusView Technologies, LLC
대리인 / 주소
Cooley LLP
인용정보
피인용 횟수 :
0인용 특허 :
39
초록▼
An HFC cable communication system comprising: a CMTS having a first attenuator to attenuate one or more upstream signals applied to the CMTS; an optical link having a dynamic range and comprising an optical receiver having a second attenuator to attenuate the upstream signal(s) and an optical transm
An HFC cable communication system comprising: a CMTS having a first attenuator to attenuate one or more upstream signals applied to the CMTS; an optical link having a dynamic range and comprising an optical receiver having a second attenuator to attenuate the upstream signal(s) and an optical transmitter having a third attenuator to attenuate the upstream signal(s); a coaxial RF link comprising one or more RF amplifiers having a fourth attenuator to attenuate the upstream signal(s); and one or more subscriber modems to generate the upstream signal(s) at respective transmit RF signal levels. The CMTS implements a long loop ALC to set the transmit RF signal level(s) based on received RF signal levels of the upstream signal(s) at the CMTS. Respective values for the first, second, third and fourth attenuators are selected based on the dynamic range of the optical link so as to facilitate implementation of the long loop ALC and effective transmission of upstream information carried by the upstream signal(s).
대표청구항▼
1. An optical node in a cable communication system, the optical node comprising: an upstream RF port to couple the optical node to an ingress-mitigated hardline RF cable plant of the cable communication system, the ingress-mitigated hardline RF cable plant conveying upstream RF information via an up
1. An optical node in a cable communication system, the optical node comprising: an upstream RF port to couple the optical node to an ingress-mitigated hardline RF cable plant of the cable communication system, the ingress-mitigated hardline RF cable plant conveying upstream RF information via an upstream channel plan in an upstream path bandwidth of the ingress-mitigated hardline RF cable plant, the upstream channel plan including a plurality of upstream RF signals, each upstream RF signal of the plurality of upstream RF signals including an encoded carrier wave having a carrier frequency in the upstream path bandwidth;at least one RF attenuator communicatively coupled to the upstream RF port to attenuate the plurality of upstream RF signals received by the optical node via the upstream RF port so as to provide a plurality of attenuated upstream RF signals; andan upstream optical transmitter communicatively coupled to the at least one RF attenuator to receive the plurality of attenuated upstream RF signals carrying the upstream RF information and to transmit corresponding upstream optical information via an optical communication link communicatively coupled to the upstream optical transmitter,wherein:the at least one attenuator of the optical node has an attenuation value to significantly mitigate substantial distortion of the upstream optical information transmitted by the upstream optical transmitter such that the upstream optical information is an effective copy of the upstream RF information;each upstream RF signal of the plurality of upstream RF signals is modulated, using quadrature amplitude modulation (QAM), with voice and/or data information constituting at least some of the upstream RF information;the plurality of upstream RF signals includes a first upstream RF signal defining a first upstream physical communication channel of the upstream channel plan in the upstream path bandwidth, the first upstream RF signal having a first carrier frequency of greater than or equal to approximately 5 MHz, and less than or equal to approximately 19.6 MHz;at least some of the plurality of upstream RF signals have different carrier frequencies to respectively define a plurality of upstream physical communication channels constituting the upstream channel plan in the upstream path bandwidth;the plurality of upstream physical communication channels occupy a substantial portion of the upstream path bandwidth;the upstream path bandwidth includes carrier frequencies in a range of from approximately 5 MHz to at least approximately 42 MHz;the upstream channel plan includes at least four physical communication channels respectively defined by upstream signals having a QAM modulation order of at least 64;the first carrier frequency of the first upstream RF signal is greater than or equal to approximately 5 MHz, and less than or equal to approximately 16.4 MHz; andthe first upstream RF signal has a QAM modulation order of at least 32. 2. The optical node of claim 1, wherein: the upstream optical transmitter has a dynamic range that is based at least in part on the upstream channel plan; andthe attenuation value of the at least one attenuator of the optical node is selected based at least in part on the dynamic range of the upstream optical transmitter. 3. An optical node in a cable communication system, the optical node comprising: an upstream RF port to couple the optical node to an ingress-mitigated hardline RF cable plant of the cable communication system, the ingress-mitigated hardline RF cable plant conveying upstream RF information via an upstream channel plan in an upstream path bandwidth of the ingress-mitigated hardline RF cable plant, the upstream channel plan including a plurality of upstream RF signals, each upstream RF signal of the plurality of upstream RF signals including an encoded carrier wave having a carrier frequency in the upstream path bandwidth;at least one RF attenuator communicatively coupled to the upstream RF port to attenuate the plurality of upstream RF signals received by the optical node via the upstream RF port so as to provide a plurality of attenuated upstream RF signals; andan upstream optical transmitter communicatively coupled to the at least one RF attenuator to receive the plurality of attenuated upstream RF signals carrying the upstream RF information and to transmit corresponding upstream optical information via an optical communication link communicatively coupled to the upstream optical transmitter,wherein:the at least one attenuator of the optical node has an attenuation value to significantly mitigate substantial distortion of the upstream optical information transmitted by the upstream optical transmitter such that the upstream optical information is an effective copy of the upstream RF information;the upstream optical transmitter has a dynamic range that is based at least in part on the upstream channel plan;the attenuation value of the at least one attenuator of the optical node is selected based at least in part on the dynamic range of the upstream optical transmitter; andthe dynamic range of the optical transmitter is based at least in part on a highest QAM modulation order of at least one upstream physical communication channel of the upstream channel plan. 4. The optical node of claim 3, wherein each upstream RF signal of the plurality of upstream RF signals is modulated, using quadrature amplitude modulation (QAM), with voice and/or data information constituting at least some of the upstream RF information. 5. The optical node of claim 4, wherein the plurality of upstream RF signals includes a first upstream RF signal defining a first upstream physical communication channel of the upstream channel plan in the upstream path bandwidth, the first upstream RF signal having a first carrier frequency of greater than or equal to approximately 5 MHz, and less than or equal to approximately 19.6 MHz. 6. The optical node of claim 5, wherein a QAM modulation order of the first upstream RF signal is at least 32. 7. The optical node of claim 5, wherein a QAM modulation order of the first upstream RF signal is at least 64. 8. The optical node of claim 5, wherein a QAM modulation order of the first upstream RF signal is at least 256. 9. The optical node of claim 5, wherein: the first carrier frequency of the first upstream RF signal is greater than or equal to approximately 5 MHz, and less than or equal to approximately 16.4 MHz;the first upstream RF signal is encoded with at least some of the voice and/or data information using a Time Division Multiple Access (TDMA) protocol or an Advanced Time Division Multiple Access (ATDMA) protocol; andan aggregate deployed upstream capacity of the upstream channel plan to convey, in a portion of the upstream path bandwidth between 5 MHz and 816.4 MHz, the at least some of the upstream RF information is at least approximately 12 Megabits per second (Mbits/s). 10. The optical node of claim 5, wherein: at least some of the plurality of upstream RF signals have different carrier frequencies to respectively define a plurality of upstream physical communication channels constituting the upstream channel plan in the upstream path bandwidth; andthe plurality of upstream physical communication channels occupy a substantial portion of the upstream path bandwidth. 11. The optical node of claim 10, wherein the upstream path bandwidth includes carrier frequencies in a range of from approximately 5 MHz to at least approximately 42 MHz. 12. The optical node of claim 11, wherein the upstream channel plan includes at least four physical communication channels respectively defined by upstream signals having a QAM modulation order of at least 64. 13. The optical node of claim 11, wherein the upstream channel plan includes at least six physical communication channels respectively defined by upstream signals having a QAM modulation order of at least 64. 14. The optical node of claim 11, wherein the upstream channel plan includes at least four physical communication channels respectively defined by upstream signals having a QAM modulation order of at least 256. 15. The optical node of claim 11, wherein the upstream channel plan includes at least six physical communication channels respectively defined by upstream signals having a QAM modulation order of at least 256. 16. The optical node of claim 3, wherein the dynamic range of the optical transmitter is based on the highest QAM modulation order of the at least one upstream physical communication channel of the channel plan and an information transfer characteristic of the upstream optical transmitter. 17. The optical node of claim 16, wherein the information transfer characteristic of the upstream optical transmitter includes a Noise Power Ratio (NPR) curve for the upstream optical transmitter. 18. The optical node of claim 17, wherein: the dynamic range of the upstream optical transmitter is defined by an input RF power window for the plurality of upstream RF signals as applied to the upstream optical transmitter;the input RF power window is determined by at least one intersection of a target carrier-to-noise (C/N) value for the highest modulation order of the at least one upstream physical communication channel of the upstream channel plan and the NPR curve;a target operating power point for the upstream optical transmitter is selected within the input RF power window; andthe attenuation value of the at least one attenuator of the optical node is selected based at least in part on the target operating power point for the upstream optical transmitter. 19. The optical node of claim 18, wherein the target operating power point for the upstream optical transmitter is selected at a midpoint of the input RF power window. 20. The optical node of claim 16, wherein the information transfer characteristic of the upstream optical transmitter includes a Bit Error Ratio (BER) curve. 21. The optical node of claim 20, wherein: the dynamic range of the upstream optical transmitter is defined by an input RF power window for the plurality of upstream RF signals as applied to the upstream optical transmitter;the input RF power window is determined by at least one intersection of a target BER value for the highest modulation order of the at least one upstream physical communication channel of the channel plan and the BER curve;a target operating power point for the upstream optical transmitter is selected within the input RF power window; andthe attenuation value of the at least one attenuator of the optical node is selected based at least in part on the target operating power point for the upstream optical transmitter. 22. The optical node of claim 16, wherein the information transfer characteristic of the upstream optical transmitter includes a Modulation Error Ratio (MER) curve. 23. The optical node of claim 22, wherein: the dynamic range of the upstream optical transmitter is defined by an input RF power window for the plurality of upstream RF signals as applied to the upstream optical transmitter;the input RF power window is determined by at least one intersection of a target MER value for the highest modulation order of the at least one upstream physical communication channel of the channel plan and the MER curve;a target operating power point for the upstream optical transmitter is selected within the input RF power window; andthe attenuation value of the at least one attenuator of the optical node is selected based at least in part on the target operating power point for the upstream optical transmitter. 24. An optical node in a cable communication system, the optical node comprising: A) an upstream RF port to couple the optical node to an RF cable plant of the cable communication system, the RF cable plant conveying upstream RF information via an upstream channel plan in an upstream path bandwidth of the RF cable plant, wherein:the upstream channel plan includes a plurality of upstream RF signals, each upstream RF signal of the plurality of upstream RF signals including an encoded carrier wave having a carrier frequency in the upstream path bandwidth;each upstream RF signal of the plurality of upstream RF signals is modulated, using quadrature amplitude modulation (QAM), with voice and/or data information constituting at least some of the upstream RF information; andat least one first upstream signal of the plurality of upstream signals has a QAM modulation order of 32 and a first carrier frequency of between approximately 5 MHz and 19.6 MHz;B) at least one RF attenuator communicatively coupled to the upstream RF port to attenuate the plurality of upstream RF signals received by the optical node via the upstream RF port so as to provide a plurality of attenuated upstream RF signals; andC) an upstream optical transmitter communicatively coupled to the at least one RF attenuator to receive the plurality of attenuated upstream RF signals carrying the upstream RF information and to transmit corresponding upstream optical information via an optical communication link communicatively coupled to the upstream optical transmitter, the upstream optical transmitter having a dynamic range that is based at least in part on:a highest QAM modulation order of at least one upstream physical communication channel of the channel plan; andan information transfer characteristic of the upstream optical transmitter,wherein:an attenuation value of the at least one attenuator of the optical node is selected based at least in part on the dynamic range of the upstream optical transmitter so as to significantly mitigate substantial distortion of the upstream optical information transmitted by the upstream optical transmitter such that the upstream optical information is an effective copy of the upstream RF information. 25. The optical node of claim 24, wherein: the dynamic range of the upstream optical transmitter is defined by an input RF power window for the plurality of upstream RF signals as applied to the upstream optical transmitter of the optical link, the input RF power window determined by at least one intersection of 1) a target carrier-to-noise (C/N) value for the highest QAM modulation order of the at least one upstream physical communication channel of the channel plan and 2) a Noise Power Ratio (NPR) curve for the upstream optical transmitter;a target operating power point for the upstream optical transmitter is selected within the input RF power window; andthe attenuation value of the at least one attenuator of the optical node is selected based at least in part on the target operating power point for the optical transmitter. 26. An optical node in a cable communication system, the optical node comprising: A) an upstream RF port to couple the optical node to an RF cable plant of the cable communication system, the RF cable plant conveying upstream RF information via an upstream channel plan in an upstream path bandwidth of the RF cable plant, wherein:the upstream channel plan includes a plurality of upstream RF signals, each upstream RF signal of the plurality of upstream RF signals including an encoded carrier wave having a carrier frequency in the upstream path bandwidth;each upstream RF signal of the plurality of upstream RF signals is modulated, using quadrature amplitude modulation (QAM), with voice and/or data information constituting at least some of the upstream RF information;at least some of the plurality of upstream signals have different carrier frequencies to respectively define a plurality of upstream physical communication channels in the upstream path bandwidth constituting a channel plan;a first upstream signal defining a first upstream physical communication channel of the plurality of upstream physical communication channels has a first carrier frequency of less than 19.6 MHz; andthe channel plan includes at least four physical communication channels respectively defined by upstream signals having a QAM modulation order of at least 64;B) at least one RF attenuator communicatively coupled to the upstream RF port to attenuate the plurality of upstream RF signals received by the optical node via the upstream RF port so as to provide a plurality of attenuated upstream RF signals; andC) an upstream optical transmitter communicatively coupled to the at least one RF attenuator to receive the plurality of attenuated upstream RF signals carrying the upstream RF information and to transmit corresponding upstream optical information via an optical communication link communicatively coupled to the upstream optical transmitter,wherein:an attenuation value of the at least one attenuator of the optical node is selected based at least in part on:a highest QAM modulation order of at least one upstream physical communication channel of the channel plan; andan information transfer characteristic of the upstream optical transmitter. 27. The optical node of claim 26, wherein: a dynamic range of the upstream optical transmitter is defined by an input RF power window for the plurality of upstream RF signals as applied to the upstream optical transmitter of the optical link, the input RF power window determined by at least one intersection of 1) a target carrier-to-noise (C/N) value for the highest QAM modulation order of the at least one upstream physical communication channel of the channel plan and 2) a Noise Power Ratio (NPR) curve for the upstream optical transmitter;a target operating power point for the upstream optical transmitter is selected within the input RF power window; andthe attenuation value of the at least one attenuator of the optical node is selected based at least in part on the target operating power point for the optical transmitter. 28. An optical node in a cable communication system, the optical node comprising: A) an upstream RF port to couple the optical node to an RF cable plant of the cable communication system, the RF cable plant conveying upstream RF information via an upstream channel plan in an upstream path bandwidth of the RF cable plant, wherein:the upstream channel plan includes a plurality of upstream RF signals, each upstream RF signal of the plurality of upstream RF signals including an encoded carrier wave having a carrier frequency in the upstream path bandwidth;each upstream RF signal of the plurality of upstream RF signals is modulated, using quadrature amplitude modulation (QAM), with voice and/or data information constituting at least some of the upstream RF information;each upstream RF signal of the plurality of upstream RF signals has a signal level at the upstream RF port corresponding to a predetermined input RF reference signal level;at least some of the plurality of upstream signals have different carrier frequencies to respectively define a plurality of upstream physical communication channels in the upstream path bandwidth constituting a channel plan; anda first upstream signal defining a first upstream physical communication channel of the plurality of upstream physical communication channels has a first carrier frequency of less than 19.6 MHz;B) at least one RF attenuator communicatively coupled to the upstream RF port to attenuate the plurality of upstream RF signals received by the optical node via the upstream RF port so as to provide a plurality of attenuated upstream RF signals; andC) an upstream optical transmitter communicatively coupled to the at least one RF attenuator to receive the plurality of attenuated upstream RF signals carrying the upstream RF information and to transmit corresponding upstream optical information via an optical communication link communicatively coupled to the upstream optical transmitter, wherein:the upstream optical transmitter has a dynamic range defined by an input RF power window for the plurality of upstream RF signals as applied to the upstream optical transmitter of the optical link, the input RF power window determined by at least one intersection of 1) a target carrier-to-noise (C/N) value for a highest QAM modulation order of at least one upstream physical communication channel of the channel plan and 2) a Noise Power Ratio (NPR) curve for the upstream optical transmitter;a target operating power point for the upstream optical transmitter is selected within the input RF power window; andan attenuation value of the at least one attenuator of the optical node is selected based at least in part on a difference between the target operating power point for the optical transmitter and the predetermined input RF reference signal level. 29. The optical node of claim 28, wherein the predetermined input RF reference signal level is 18-19 dBmV.
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