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The title should not exceed 200 characters to ensure compatibility with file systems.'''\n\nbelow is an example of the expected json dictionary response format, with the default inputs:\n{'api_response': 'This is the reply to your request.', 'generate_title': 'Short_Title_for_Query'}\n-----------------------------------------------------------------------------\n#prompt#\n\nthe following image is for a website, i am seeking ideal SEO standards foir maximum searchability and the site is mainly for data and refference material\n        \n    BASE_URL:\n    www.thedailydialectics.com\n    \n    url:\n    https://thedailydialectics.com/imgs/sommerfeld-goubau/google/QUASAI-WIRELESS COMMUNICATION SYSTEM.pdf\n    \n    title:\n    None\n    \n    description:\n    None\n    with this format of output:\n    ### Image Name:\n`image.jpg`\n\n### Alt Text:\n`text`\n\n### Title Tag:\n`title`\n\n### Description:\n`description`\n\n### Additional Metadata:\n- **Caption:** \"caption\"\n- **Keywords:** Keywords,Keywords,Keywords,Keywords,...\n\n### URL:\n`URL`\n\n        \n        content:\n        US 2017/0237497 Al\n\n[0085] Strand Mount Device\n\n[0086] FIG. 12 is a block diagram of an example strand\nmount device 220. As previously explained with reference to\nFIGS. 2A and 2B, multiple strand mount devices 220 may be\nmounted on a power line 204 connected to the network\ndevice 210. Each strand mount device 220 is positioned in\na way that allows for near line-of-sight with a house 32 of\na user 30. In some implementations, the strand mount device\n220 receives the SG IF, SG control, and SG reference signals\nfrom the SG launcher 300 via the power line 204. The circuit\n1000 may amplify and power split the SG IF, SG control,\nand SG reference signals for communication to a down-\nstream SG launcher 300 via the power line 204.\n\n[0087] Additionally, the circuit 1000 may provide the SG\nIE, SG control, and SG reference signals split by the power\nsplitters of the circuit to a triplexer 1205 associated with the\nlocal RFIC 224. In some implementations, the strand mount\nlevice 220 implements frequency shifts/divisions via the\nfirst triplexer 1002 associated with the circuit 1000 and the\ntriplexer 1205 associated with the local RFIC 224. For\ninstance, block 1202 of the strand mount device 220 shifts\nthe SG IF (e.g., the intermediate frequency carrying com-\nmunication data) to a BBIC IF; block 1204 of the strand\nmount device 220 shifts the SG control frequency (fre-\nuency identifying the destination of the communication\ndata, i.e., which end user, code book etc.) to a BBIC control\nfrequency; and block 1206 divides the SG reference fre-\nquency to the BBIC reference frequency. This shift allows\nthe RFIC 224 to broadcast the signals over the mm-wave\nspectrum to the client device(s) 250. Thereafter, the triplexer\n920 provides the BBIC IF, BBIC control, and BBIC refer-\nence signals to the local RFIC 224 and the RFIC 224\nwirelessly broadcasts the signals over a RF communication\nlink 226 to a client device 250 or another stand mount device\n220.\n\n[0088] The strand mount device 220 may further include\na current transformer 700 (FIGS. 7A and 7B) and/or an\nenergy harvesting device 1212 electrically connected to the\nlocal RFIC 224 and configured to inductively tap power\nfrom the power line 204 and supply 1216 the tapped power\nto the RFIC 224. In some examples, the power supply 1216\nprovides the tapped power to a battery backup device 1218\nconfigured to store power for use by the RFIC 224 and/or\namplifiers 1008 associated with the circuit 1000. The strand\nmount device 220 may include utility monitoring hardware\n1214 in communication with the current transformer 700\nand/or the energy harvesting device 1212. The utility moni-\ntoring hardware 1214 is configured to receive a power signal\nfrom the current transformer 700 or the energy harvester\n1212 and transmit utility monitoring data via a transceiver\n1220 to a network operations center (NOC) in communica-\ntion with the strand mount device 220 (e.g., to notify the\nNOC of any issues with the power line 204.\n\n[0089] User Receiving Device\n\n[0090] FIG. 13 illustrates a user receiving device 250 that\nincludes a standard 802.1lad device 250, which includes\nmultiple RFICs so that the antenna gain and transmit Effec-\ntive Isotropic Radiated Power (EIRP) allows the link 226 to\nclose to the strand mount device 220. The client device 250\nincludes a BBIC 222 in communication with the ONU 60,\n60a (e.g., bi-directional transceiver) associated with a prem-\nises 32 of an end user 30, 30a. In some examples, the ONU\n60 implements a network processor 62 for monitoring\n\nann\n\nAug. 17, 2017\n\nnetwork parameters of the quasi-wireless edge network 200\nthat replaces the last section of access fiber and the fiber drop\nreaching the ONU 60.\n\n[0091] Alternative Implementation\n\n[0092] Referring to FIG. 14, in an alternative implemen-\ntation, a custom point-to-multipoint wireline transceiver\n1402 is in communication with the MV power line 204 and\nthe OLT 50 and utilizes the allowed frequencies (avoiding\nNTIA masked frequencies). To reduce the power consump-\ntion of such a system, the transceiver 1402 could be\ndesigned such that it is a PHY replacement for the wireless\nlinks. This would allow the strand mount devices 220 to\navoid having to traverse the network stack reducing power\nconsumption. In the example shown, the strand mount\ndevices 220 are disposed on the MV power line 204 and the\nin-house user devices 250 in wireless communication with\nthe strand mount devices 220. Each client device 250\nprovides wireless communications from the strand mount\ndevices 220 to a corresponding ONU 60 associated with the\ncorresponding premises 32 of the corresponding end user\n30.\n\n[0093] Alternative Use Case\n\n[0094] The 802.11ad standard was conceived primarily as\na connectivity solution for consumer data consumption\nwithin the home. A challenge of the 802.1lad frequency\nused is the need for line of sight between the access point\nand the connected device. This is a challenge since in a home\nthe access point is often in a corner of a house while the\ndevices may be in any room. Referring to FIG. 15, an\nalternative use for the quasi-wireless edge network 200 is\nwithin a house 32. In-home coaxial cables 1504 may be used\nin place of the Goubau launchers and medium voltage power\nlines 1506 for the purpose of distributing remote 802.1lad\naccess point radio heads in various rooms across the house.\nAs the frequencies of the IF traffic, control signals and Ref\ncan be moved to frequencies not used by MOCA, DOCSIS\nor standard cable television transmission, it may be possible\nto share the coaxial cables using diplexers to combine the\nsignals. 802.1lad multi gigabit RFICs can in this way be\nplaced around the home allowing high speed connections to\ndevices in multiple rooms.\n\n[0095] FIG. 16 illustrates a method 1600 for delivering a\ncommunication signal. At block 1602, the method 1600\nincludes receiving, at an optical transceiver 1102 and an\noptical communication 23. At block 1604, the method 1600\nincludes constructing, at a baseband integrated circuit 222 in\ncommunication with the optical transceiver 1102, a radio\nfrequency communication 225 (e.g., the intermediate fre-\nquency data and control signals) based on the optical com-\nmunication 23. At block 1606, the method 1600 also\nincludes transmitting the radio frequency communication\n225 from a Sommerfeld-Goubau launcher 300, 300a in\ncommunication with the baseband integrated circuit 222 as\na surface wave 301 along a power line 204 to a strand mount\ndevice 220 disposed on the power line 204. The strand\nmount device 220 is configured to receive the radio fre-\nquency communication 225 and wirelessly transmit the\nradio frequency communication 225 (e.g., via a wireless\nlink) to a user device 250.\n\n[0096] In some implementations, the method 1600\nincludes processing the optical communication 23 at a\nnetwork processor 211 in communication with the optical\ntransceiver 1102 and the baseband integrated circuit 222.\nThe step of constructing the radio frequency communication\n\n        "
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